Chromosomal mapping of four different integration sites of Moloney murine leukemia virus including the locus for alpha 1(I) collagen in mouse

Infection of mouse embryos with Moloney murine leukemia virus (M-MuLV) has yielded several mouse substrains with stable germ line integration of retroviral DNA at distinct chromosomal loci (Mov loci; Jaenisch et al., 1981). There is evidence that flanking DNA sequences can have an effect on virus expression and, conversely, inserted viral DNA may affect the expression of adjacent host genes. As part of our studies on the interaction of inserted M-MuLV with the mouse genome, we have chromosomally mapped four different Mov loci by hybridizing single-copy mouse sequences, flanking the proviral DNA, to interspecies somatic cell hybrids. Furthermore, these sequences were assigned regionally by in situ hybridization to mouse metaphase chromosomes. In Mov-13 mice, M-MuLV had inserted into the alpha 1(I) collagen gene leading to early embryonic death in homozygotes. We have assigned this locus to the distal region of chromosome 11. Thus, the alpha 1(I) collagen gene is part of an evolutionarily conserved linkage group with the homologous genes on human chromosome 17. Three other proviral integration sites were mapped to chromosome 1, bands BC (Mov-7), chromosome 11, bands BC (Mov-9), and chromosome 3, bands FG (Mov-10). The Mov-10-specific probe detects an EcoRI-specific restriction fragment length polymorphism, which can make this probe a useful genetic marker.     

Human-mouse interspecies collagen I heterotrimer is functional during embryonic development of Mov13 mutant mouse embryos.

To investigate whether the human pro alpha 1(I) collagen chain could form an in vivo functional interspecies heterotrimer with the mouse pro alpha 2(I) collagen chain, we introduced the human COL1A1 gene into Mov13 mice which have a functional deletion of the endogenous COL1A1 gene. Transgenic mouse strains (HucI and HucII) carrying the human COL1A1 gene were first generated by microinjecting the COL1A1 gene into wild-type mouse embryos. Genetic evidence indicated that the transgene in the HucI strain was closely linked to the endogenous mouse COL1A1 gene and was X linked in the HucII transgenic strain. Northern (RNA) blot and S1 protection analyses showed that the transgene was expressed in the appropriate tissue-specific manner and as efficiently as the endogenous COL1A1 gene. HucII mice were crossed with Mov13 mice to transfer the human transgene into the mutant strain. Whereas homozygous Mov13 embryos die between days 13 and 14 of gestation, the presence of the transgene permitted apparently normal development of the mutant embryos to birth. This indicated that the mouse-human interspecies collagen I heterotrimer was functional in the animal. The rescue was, however, only partial, as all homozygotes died within 36 h after delivery, with signs of internal bleeding. This could have been due to a functional defect in the interspecies hybrid collagen. Extensive analysis failed to reveal any biochemical or morphological abnormalities of the collagen I molecules in Mov13-HucII embryos. This may indicate that there was a subtle functional defect of the interspecies hybrid protein which was not revealed by our analysis or that another gene has been mutated by the retroviral insertion in the Mov13 mutant strain.     

Germ line integration of moloney leukemia virus: Effect of homozygosity at the M-MuLV locus

Mice genetically transmitting the exogenous Moloney leukemia virus (M-MuLV) have been previously derived. These animals carried one copy of M-MuLV DNA in their germ line and were heterozygous for the M-MuLV locus (Jaenisch, 1976).Experiments were performed to investigate whether homozygosity at the M-MuLV locus would be compatible with normal development. Animals heterozygous for the M-MuLV locus were mated [♀ (+?) × ♂(+?)] and the genotype of the off-spring was analyzed. Molecular hybridization experiments revealed three classes of offspring carrying two copies (++), one copy (+?) and no (??) M-MuLV-specific DNA sequences, respectively, in their liver DNA. Genetic experiments indicated that males of the first class transmitted the virus to 100% of their offspring, males of the second class to 50% and males of the third class not at all when mated with normal females. These results demonstrated that homozygosity at the M-MuLV locus has no detectable effect on normal development of the animals and that the M-MuLV gene is transmitted from one generation to the next strictly according to Mendelian expectations. Development of M-MuLV-induced leukemia is not influenced by the genotype of these animals-that is, animals carrying two or one copies of M-MuLV in their germ line or animals congenitally infected from the mother developed disease at similar rates.     

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.     

Normal epithelial branching morphogenesis in the absence of collagen I

Interstitial collagens are thought to mediate epithelial-mesenchymal interactions during organogenesis. We have used the collagen I-deficient mouse mutant Mov13 to directly investigate the role of this major representative of the interstitial collagens in epithelial branching morphogenesis. Since homozygous embryos die at midgestation, we have studied the development of organ rudiments from Mov13 homozygous (i.e., collagen I-deficient), heterozygous, and wild-type embryos in culture. Development of all explants, including lung, kidney, salivary glands, pancreas, and skin, was normal by light and electron microscopic criteria and was independent of the genotype of the donor embryo. Metabolic labeling and immune staining verified the complete absence of collagen I in homozygous explants while revealing substantial production of collagens III and V in explants of all three genotypes. These results indicate either that collagen I has no role in the morphogenesis of these organs, or that its function is shared, or can be substituted for, by other fibrillar collagens.     

Embryonic lethal mutation in mouse collagen I gene causes rupture of blood vessels and is associated with erythropoietic and mesenchymal cell death

The role of collagen I for midgestation development was studied in homozygous Mov 13 embryos, which cannot synthesize alpha 1(1) mRNA as a result of insertional mutagenesis and most of which die between day 12 and 14 of gestation. No type I collagen was detected in mutant embryos, while the distribution of other collagens, laminin, and fibronectin was not affected. Mutant embryos develop normally up to day 12 of gestation, suggesting that collagen I has no essential role in the early phase of morphogenesis. The first pathological events were detected in hemopoietic cells of the liver, followed by necroses of mesenchymal cells in other parts of the embryo. The sudden death is caused by the rupture of a major blood vessel, indicating an important role for collagen I in establishing the mechanical stability of the circulatory system. Our results furthermore suggest that complex cell interactions in embryonic development such as those in early hemopoiesis may depend on the presence of collagen type I.     

Production of Viable Homozygous, Doubled Haploid Channel Catfish (Ictalurus punctatus)

Production of doubled haploids via mitotic gynogenesis is a useful tool for the creation of completely inbred fish. In order to produce viable doubled haploid channel catfish, we utilized hydrostatic pressure or thermal treatments on eggs fertilized with sperm that had been exposed to ultraviolet light. At 1.5 h post-fertilization, the embryos were exposed to either 590 kg/cm² hydrostatic pressure for 3 min, 37°C for 5 min, or 41°C for 3 min. In the pressure-treated group, only 21 offspring hatched from five spawns with family sizes of one, two, two, four, and 12 offspring each. Eight embryos from the 37°C treatment and 32 embryos from the 41°C treatment survived to hatch. Genotype analysis using microsatellite loci demonstrated all 21 offspring resulting from pressure treatment were homozygous at the 64 loci tested, and none contained alleles unique to the donor male. Eleven of 32 offspring from the 41°C treatment were homozygous at the 18 loci tested, while 21 offspring were heterozygous at six to 12 of these loci. Again, no offspring contained alleles unique to the donor male. However, all eight offspring from the 37°C treatment were heterozygous at multiple loci, and one contained unambiguous paternal alleles. These experiments demonstrated our ability to produce viable homozygous, doubled haploid channel catfish. Doubled haploid catfish can be used to create completely inbred populations for genetic analyses, and homozygous genomic templates will be useful in gene identification and genome characterization.     

Cranial effects of retinoic acid in the loop-tail (Lp) mutant mouse

The effects of retinoic acid (RA) on the manifestation and nature of neural tube defects (NTD) in heterozygous embryos of mutant mice carrying the gene loop-tail (Lp) and in normal (+/+) littermates and embryos from normal homozygous matings were compared with NTD that occur in untreated abnormal homozygous (Lp/Lp) embryos. A single intraperitoneal dose (5 mg/kg) of RA administered at 9 AM or 3 PM on day 8 of gestation induced NTD in +/+ as well as Lp/+ embryos removed on day 12 of gestation. All of the NTD were confined to the brain and consisted of exencephaly involving the diencephalon, mesencephalon, and metencephalon. In neither phenotype (Lp/+; +/+) was the massive exencephaly and myeloschisis characteristic of untreated Lp/Lp embryos produced; thus, it is possible that the teratogenic mechanisms of RA-induced defects and of Lp-induced defects may differ.     

Bulging medial edge epithelial cells and palatal fusion

The surface of the medial edge epithelium of embryonic day 12, 13 and 14 mouse palatal shelves was observed utilising Environmental Scanning Electron Microscopy (ESEM). This technique offers the advantage of visualisation of biological samples after short fixation times in their natural hydrated state. Bulging epithelial cells were observed consistently on the medial edge epithelium prior to palatal shelf fusion. Additionally, we have used ESEM to compare the morphology and surface features of palatal shelves from embryonic day 13 to 16 mouse embryos that are homozygous null (TGF-beta3 -/-), heterozygous (TGF-beta3 +/-) or homozygous normal (TGF-beta3 +/+) for transforming growth factor beta-3 (TGF-beta3). At embryonic day 15 and 16 most TGF-beta3 +/- and +/+ embryos showed total palatal fusion, whilst all TGF-beta3 null mutants had cleft palate: the middle third of the palatal shelves had adhered, leaving an anterior and posterior cleft. From embryonic day 14 to 16 abundant cells were observed bulging on the medial edge epithelial surface of palates from the TGF-beta3 +/- and +/+ embryos. However, they were never seen in the TGF-beta3 null embryos, suggesting that these surface bulges might be important in palatal fusion and that their normal differentiation is induced by TGF-beta3. The expression pattern of E-Cadherin, beta-catenin, chondroitin sulphate proteoglycan, beta-Actin and vinculin as assayed by immunocytochemistry in these cells shows specific variations that suggest their importance in palatal shelf adhesion.     

PINCH1 plays an essential role in early murine embryonic development but is dispensable in ventricular cardiomyocytes

PINCH1, an adaptor protein composed of five LIM domains, mediates protein-protein interactions and functions as a component of the integrin-integrin-linked kinase (ILK) complex. The integrin-ILK signaling complex plays a pivotal role in cell motility, proliferation, and survival during embryonic development of many animal species. To elucidate the physiological function of PINCH1 in mouse embryonic development, we have deleted the mouse PINCH1 gene by homologous recombination. Mice heterozygous for PINCH1 are viable and indistinguishable from wild-type littermates. However, no viable homozygous offspring were observed from PINCH1+/- intercrosses. Histological analysis of homozygous mutant embryos revealed that they had a disorganized egg cylinder by E5.5, which degenerated by E6.5. Furthermore, E5.5 PINCH1-/- embryos exhibited decreased cell proliferation and excessive cell death. We have also generated and analyzed mice in which PINCH1 has been specifically deleted in ventricular cardiomyocytes. These mice exhibit no basal phenotype, with respect to mouse survival, cardiac histology, or cardiac function as measured by echocardiography. Altogether, these data indicate that PINCH1 plays an essential role in early murine embryonic development but is dispensable in ventricular cardiomyocytes.     

Cse1l is essential for early embryonic growth and development

The CSE1L gene, the human homologue of the yeast chromosome segregation gene CSE1, is a nuclear transport factor that plays a role in proliferation as well as in apoptosis. CSE1 and CSE1L are essential genes in Saccharomyces cerevisiae and mammalian cells, as shown by conditional yeast mutants and mammalian cell culture experiments with antisense-mediated depletion of CSE1L. To analyze whether CSE1L is also essential in vivo and whether its absence can be compensated for by other genes or mechanisms, we have cloned the murine CSE1L gene (Cse1l) and analyzed its tissue- and development-specific expression: Cse1l was detected at embryonic day 7.0 (E7.0), E11.0, E15.0, and E17.0, and in adults, high expression was observed in proliferating tissues. Subsequently, we inactivated the Cse1l gene in embryonic stem cells to generate heterozygous and homozygous knockout mice. Mice heterozygous for Cse1l appear normal and are fertile. However, no homozygous pups were born after interbreeding of heterozygous mice. In 30 heterozygote interbreeding experiments, 50 Cse1l wild-type mice and 100 heterozygotes were born but no animal with both Cse1l alleles deleted was born. Embryo analyses showed that homozygous mutant embryos were already disorganized and degenerated by E5.5. This implicates with high significance (P < 0.0001, Pearson chi-square test) an embryonically lethal phenotype of homozygous murine CSE1 deficiency and suggests that Cse1l plays a critical role in early embryonic development.     

Chromosomal position and specific demethylation in enhancer sequences of germ line-transmitted retroviral genomes during mouse development.

The methylation pattern of the germ line-transmitted Moloney leukemia proviral genome was analyzed in DNA of sperm, of day-12 and day-17 embryos, and of adult mice from six different Mov substrains. At day 12 of gestation, all 50 testable CpG sites in the individual viral genomes as well as sites in flanking host sequences were highly methylated. Some sites were unmethylated in sperm, indicating de novo methylation of unique DNA sequences during normal mouse development. At subsequent stages of development, specific CpG sites which were localized exclusively in the 5' and 3' enhancer regions of the long terminal repeat became progressively demethylated in all six proviruses. The extent of enhancer demethylation, however, was tissue specific and strongly affected by the chromosomal position of the respective proviral genome. This position-dependent demethylation of enhancer sequences was not accompanied by a similar change within the flanking host sequences, which remained virtually unchanged. Our results indicate that viral enhancer sequences, but not other sequences in the M-MuLV genome, may have an intrinsic ability to interact with cellular proteins, which can perturb the interaction of the methylase with DNA. Demethylation of enhancer sequences is not sufficient for gene expression but may be a necessary event which enables the enhancer to respond to developmental signals which ultimately lead to gene activation.     

Perinatal lethality (ple): a mutation caused by integration of a transgene into distal mouse chromosome 15

We have used cytogenetic and recombinational analysis to determine the position of a transgene integrated into the mouse genome. The transgene maps to band F on the physical map of mouse chromosome 15 by in situ analysis and is tightly linked genetically to a cluster of loci that include the mutations caracul (Ca) and microcytic anemia (mk). Genetic analysis of the offspring of noninbred animals carrying the transgene and marker loci demonstrates a significant deficiency of homozygous progeny at weaning. When inbred mice heterozygous for the transgene are mated, about one-quarter of their offspring are homozygous; none of these animals survives more than 1 day after birth. It appears likely that a recessive insertional mutation has occurred as a result of transgene integration into a locus required for postnatal viability. We call this mutation transgenic perinatal lethality (Tg.ple).     

Disruption of muREC2/RAD51L1 in mice results in early embryonic lethality which can Be partially rescued in a p53(-/-) background

muREC2/RAD51L1 is a radiation-inducible gene that regulates cell cycle progression. To elucidate the biological function of muREC2/RAD51L1, the gene was disrupted in embryonic stem cells by homologous recombination. Mice heterozygous for muREC2/RAD51L1 appear normal and fertile; however, no homozygous pups were born after interbreeding of heterozygous mice. Timed pregnancy studies showed that homozygous mutant embryos were severely retarded in growth as early as ca. 5 days gestation (E5.5) and were completely resorbed by E8.5. Mutant blastocyst outgrowth was also severely impaired in a double-knockout embryo, but embryonic development did progress further in a p53-null background. These results suggest that muREC2/RAD51L1 plays a role in cell proliferation and early embryonic development, perhaps through interaction with p53.     

Mutation in microsatellite repeats of DNA and embryonal death in humans

In the analysis of tetranucleotide DNA repeats inheritance carried out in 55 families with a history of spontaneous miscarriages and normal karyotypes in respect to 21 loci located on seven autosomes, 8 embryos (14.5%) demonstrating 12 cases of the presence of alleles absent in both parents were described. The study of chromosome segregation using other DNA markers permitted highly probable exclusion of false paternity as well as uniparental disomy as the reasons for parent/child allele mismatches. The high probability of paternity together with the presence of a "new" allele at any offspring locus points to the mutation having occurred during game-togenesis in one of the parents. Examination of mutation in spontaneous abortuses revealed an increased number of tandem repeat units at microsatellite loci in three cases and an decreased number of these repeats in six cases. In two abortuses, a third allele absent in both parents, which resulted from a somatic mutation that occurred during embryonic development, was observed. The prevalence of the male germline mutations, revealed during investigation of the mutation origin, was probably associated with an increased number of DNA replication cycles in sperm compared to the oocytes. In spontaneous abortuses, the mean mutation rate of the tetranucleotide repeat complexes analyzed was 9.8 x 10(-3) per locus per gamete per generation. This was about five times higher than the spontaneous mutation rate of these STR loci. It can be suggested that genome instability detected at the level of repeated DNA sequences can involve not only genetically neutral loci but also active genomic regions crucial for embryonic viability. This results in cell death and termination of embryonic development. Our findings indicate that the death of embryos with normal karyotypes in most cases is associated with an increased frequency of germline and somatic microsatellite mutations. The data of the present study also provide a practical tool for the quantitative evaluation of this phenomenon and for the analysis of the reasons for miscarriages and embryonic death in certain families.     

Targeted deletion of fatty acid transport protein-4 results in early embryonic lethality

Fatty acid transport protein-4 (FATP4) is the major FATP in the small intestine. We previously demonstrated, using in vitro antisense experiments, that FATP4 is required for fatty acid uptake into intestinal epithelial cells. To further examine the physiological role of FATP4, mice carrying a targeted deletion of FATP4 were generated. Deletion of one allele of FATP4 resulted in 48% reduction of FATP4 protein levels and a 40% reduction of fatty acid uptake by isolated enterocytes. However, loss of one FATP4 allele did not cause any detectable effects on fat absorption on either a normal or a high fat diet. Deletion of both FATP4 alleles resulted in embryonic lethality as crosses between heterozygous FATP4 parents resulted in no homozygous offspring; furthermore, no homozygous embryos were detected as early as day 9.5 of gestation. Early embryonic lethality has been observed with deletion of other genes involved in lipid absorption in the small intestine, namely microsomal triglyceride transfer protein and apolipoprotein B, and has been attributed to a requirement for fat absorption early in embryonic development across the visceral endoderm. In mice, the extraembryonic endoderm supplies nutrients to the embryo prior to development of a chorioallantoic placenta. In wild-type mice we found that FATP4 protein is highly expressed by the epithelial cells of the visceral endoderm and localized to the brush-border membrane of extraembryonic endodermal cells. This localization is consistent with a role for FATP4 in fat absorption in early embryogenesis and suggests a novel requirement for FATP4 function during development.     

Alternatively Spliced Tissue Factor Is Not Sufficient for Embryonic Development

Tissue factor (TF) triggers blood coagulation and is translated from two mRNA splice isoforms, encoding membrane-anchored full-length TF (flTF) and soluble alternatively-spliced TF (asTF). The complete knockout of TF in mice causes embryonic lethality associated with failure of the yolk sac vasculature. Although asTF plays roles in postnatal angiogenesis, it is unknown whether it activates coagulation sufficiently or makes previously unrecognized contributions to sustaining integrity of embryonic yolk sac vessels. Using gene knock-in into the mouse TF locus, homozygous asTF knock-in (asTFKI) mice, which express murine asTF in the absence of flTF, exhibited embryonic lethality between day 9.5 and 10.5. Day 9.5 homozygous asTFKI embryos expressed asTF protein, but no procoagulant activity was detectable in a plasma clotting assay. Although the α-smooth-muscle-actin positive mesodermal layer as well as blood islands developed similarly in day 8.5 wild-type or homozygous asTFKI embryos, erythrocytes were progressively lost from disintegrating yolk sac vessels of asTFKI embryos by day 10.5. These data show that in the absence of flTF, asTF expressed during embryonic development has no measurable procoagulant activity, does not support embryonic vessel stability by non-coagulant mechanisms, and fails to maintain a functional vasculature and embryonic survival.     

Identification of the homozygous recessive genotype for the deficiency of uridine monophosphate synthase in 35-day bovine embryos.

Holstein-Friesian cattle heterozygous for the deficiency of uridine monophosphate (UMP) synthase have half-normal activity of UMP synthase. The homozygous recessive genotype would result in little or no activity, has not been observed among live animals and apparently leads to embryonic mortality at approximately Day 40 of gestation. Activity of UMP synthase averaged 2.74 +/- 0.61 units/mg protein for 19 obligatory normal embryos (from normal x normal matings). Activity for 18 embryos from heterozygote x heterozygote matings yielded three non-overlapping groups as follows: (i) five presumed normals with greater than two-thirds normal activity, (ii) ten apparent heterozygotes with one-third to two-thirds normal activity and (iii) three putative homozygous recessive embryos with less than one-third normal activity. The distribution among these groups was consistent with the 1:2:1 ratio expected for autosomal inheritance. Conception of embryos homozygous recessive for this disorder was demonstrated.