Ped gene expression by embryos cultured in vitro

The rate of cleavage division of preimplantation mouse embryos has been shown to be influenced by the Ped gene, a gene linked to the H-2 complex, the major histocompatibility complex of the mouse. There are two functional alleles of the Ped gene, slow and fast. To examine Ped gene expression outside of the maternal uterine environment, embryos from inbred and congenic mouse strains were cultured in vitro, in chemically defined medium, for various lengths of time. The results of these studies show that the difference in the rate of cleavage division between slow-developing strains (Ped slow) and fast-developing strains (Ped fast) is maintained in vitro. Thus, the Ped gene phenotype of developing embryos is an intrinsic property of the embryos themselves.     

Analysis of Qa-2 antigen expression by preimplantation mouse embryos: possible relationship to the preimplantation-embryo-development (Ped) gene product

The preimplantation-embryo-development (Ped) gene, a gene that controls the cleavage rate of preimplantation mouse embryos, maps to the Qa-2 subregion of the mouse major histocompatibility complex (MHC). A highly sensitive enzyme-linked immunosorbent assay (ELISA) procedure was used to detect Qa-2 antigens on mouse embryos. The use of a monoclonal antibody specific for Qa-2 antigens showed that Qa-2 antigens were present on oocytes, 2-cell, 8-cell, and blastocyst-stage embryos, with the greatest expression found on blastocysts. Expression of Qa-2 antigens by the embryos correlated completely with Ped gene phenotype. Those embryos expressing the fast Ped allele showed the presence of Qa-2 antigens (Qa-2a mice), whereas those embryos expressing the slow Ped allele showed the absence of Qa-2 antigens (Qa-2b mice). It is hypothesized that the Qa-2 antigen may be the Ped gene product.     

Influence of the preimplantation-embryo-development (ped) gene on mouse blastocyst differentiation

Mouse preimplantation embryonic cleavage rate is dependent upon the presence or absence of the Preimplantation-embryo-development (Ped) gene; which is linked to the Qa-2 subregion of the H-2 complex. Expression of Qa-2 antigens by fast developing mouse embryos correlates with Ped gene pheno-type: Qa-2(a). It is not known if the Ped gene (Qa-2(a)) participates in cell differentiation in the preimplantation mouse blastocyst. Therefore, the study objective was to determine the differentiation of cells to the inner cell mass (ICM) and trophectoderm (TE) in Qa-2(a) positive (Ped +) and Qa-2(a) negative (Ped -) mouse blastocysts. One-cell stage embryos were recovered from the excised oviducts of PMSG (5 IU) and hCG (5 IU) primed virgin female (3-4 weeks) BALB/cByJ (Qa-2(a): Ped -) and BALB/cJ (Qa-2(a): Ped +) mice mated to fertile males (12+ weeks). Embryos were collected, 14 hr after hCG, and cultured in modified alpha-MEM, to the hatched blastocyst stage in an atmosphere of 5% CO2 in air, 95% relative humidity at 37 degrees C. Cell differentiation was determined by differential staining (bis-benzimide and propidium iodide) and fluorescence microscopy. Data were analyzed by Students t-test. There was no significant difference in total cell number between BALB/cJ (mean 139) and BALB/cByJ (mean 143) embryos. A significant difference (p < 0.001) was found in the number of cells differentiating to the ICM between BALB/cJ (mean 59.0) and BALB/cByJ (mean 29.0) mouse embryos. The number of cells differentiating to the TE, between BALB/cJ (mean 80.0) and BALB/cByJ (mean 114) embryos, approached significance (p = 0.062). The results suggest that the Ped gene (Qa-2(a)) may have an influential role in preimplantation blastocyst cell differentiation. Additional studies are warranted to further elucidate the role of the Ped gene in preimplantation embryo development and blastocyst formation.     

Removal of Qa-2 antigen alters the Ped gene phenotype of preimplantation mouse embryos.

Embryo survival is influenced by both genetic and environmental factors. Previous research in our laboratory has identified one gene associated with embryonic survival, the Ped gene, a gene that is linked to the major histocompatibility complex (MHC) of the mouse. The Ped gene has been shown to influence the rate of preimplantation embryonic cleavage division, as well as litter size, birth weight, and weaning weight. Genetic mapping of the Ped gene has located it in the Q region of the MHC and has suggested that possible Q region genes encoding the Ped gene are Q3, Q5, Q6, Q7, Q8, and/or Q9. Whereas the protein products of the Q3 and Q5 genes are unknown, the protein product of the very similar Q6, Q7, Q8, and Q9 genes is the Qa-2 antigen. Two forms of membrane-bound Qa-2 antigen are known: glycosylphosphatidylinositol (GPI)-linked and transmembrane bound. Only the GPI-linked form is sensitive to cleavage by phosphatidylinositol phospholipase C (PI-PLC). The first purpose of the present study was to determine the nature of the linkage of the Qa-2 antigen to the cell surface of preimplantation mouse embryos. It was found that all detectable Qa-2 antigen on the embryonic cell surface is sensitive to cleavage by PI-PLC and is therefore bound to the cell membrane by a GPI linkage. Furthermore, removal of Qa-2 antigen from the embryonic cell surface slows down the rate of development of preimplantation mouse embryos. These results suggest the likelihood that the Qa-2 antigen is the Ped gene product.     

Ped gene deletion polymorphism frequency in wild mice

The Ped gene influences the rate of cleavage of preimplantation embryos and their subsequent survival. Embryos that express the product of the Ped gene, Qa-2 protein, cleave at a faster rate than embryos with an absence of Qa-2 protein. In addition, the Ped gene has pleiotropic effects on reproduction. Thus, there is a reproductive advantage to those mouse strains that are Qa-2 positive. The presence or absence of Qa-2 is reflected at the DNA level by the presence or absence (deletion polymorphism) of the gene(s) encoding Qa-2 protein. Many inbred and wild-derived mouse strains have been characterized as Qa-2 positive or negative, but no previous studies have looked at the distribution of the Ped gene in a population of free-living wild mice. The purpose of this study was to determine the Ped gene deletion polymorphism frequency in a sample of free-living wild mice. Twenty-nine mice were collected and identified as Mus musculus. Genomic DNA extraction was performed on tail tips, and PCR was used to amplify a region from the Ped gene. Known Qa-2 positive and negative mice were used as controls. Results showed that all 29 wild mice were positive for the Ped gene. Since the Ped gene is dominant and provides a reproductive advantage, it is not surprising that all of the wild mice were Qa-2 positive. However, our assay could not distinguish homozygous from heterozygous mice. It is possible that the Qa-2 deletion polymorphism is segregating in the population, and a larger sample size would identify some Qa-2 negative mice.     

Identification of two major histocompatibility complex class Ib genes, Q7 and Q9, as the Ped gene in the mouse

The Ped (preimplantation embryonic development) gene influences the rate of preimplantation embryonic development and subsequent embryonic survival. The protein product of the Ped gene, the Qa-2 protein, is a major histocompatibility complex (MHC) class Ib protein. There are two alleles of the Ped gene, fast (Qa-2 [+]) and slow (Qa-2 [-]). Qa-2 is encoded by four very similar MHC class Ib genes: Q6, Q7, Q8, and Q9. Recent research in our laboratory has shown that the Ped phenotype is potentially encoded by the Q7 and/or Q9 gene because the Q7 and Q9 genes, but not the Q6 or Q8 gene, are expressed during preimplantation mouse embryonic development. In this study we utilized microinjection of transgenes to assess the functional roles of both the Q7 and Q9 genes in control of the rate of preimplantation development. The Q7 gene, the Q9 gene, and a combination of the Q7 and Q9 genes were microinjected into Ped slow zygotes, and the Ped phenotype and cell surface expression of Qa-2 protein were assayed after a 72-h or 96-h incubation period. We found that the microinjected individual Q7 and Q9 genes increased the rate of preimplantation development. Simultaneous injection of the Q7 and Q9 genes did not have a synergistic effect on the Ped phenotype. Microinjection of the Q7 and/or Q9 genes resulted in protein expression in 10-25% of the microinjected embryos. These results show that both the Q7 and Q9 genes encode the mouse Ped phenotype.     

Selection in favor of the Ped fast haplotype occurs between mid-gestation and birth

 The preimplantation embryo development (Ped) gene that encodes the class Ib major histocompatibility complex protein Qa-2 influences the rate of embryonic cleavage during the preimplantation stages of development. Embryos from strains of mice that lack the Ped gene cleave slowly, while embryos that have a functional Ped gene cleave more rapidly. This effect is observed both in vivo and in vitro with the Ped fast haplotype showing dominance over the Ped slow haplotype. The Ped gene is associated with pleiotropic effects on reproduction. Certain strains of mice lacking the Ped gene (Ped slow) have smaller litters and the pups weigh less at birth and at weaning. Previously our laboratory reported that in litters derived from Ped fast/slow F1 mice backcrossed to the slow/slow parent, there were significantly more Ped fast pups than the 50% expected, at two months of age. This implies that there is selection in favor of the Ped fast haplotype at some point during development. The present study was designed to determine at what point during development selection occurs. Using a polymerase chain reaction assay, we determined that selection does not occur by days post coitus 14.5. However, our results show that there are significantly more Ped fast pups than Ped slow pups remaining in backcross litters just after birth, indicating that selection in favor of the Ped fast haplotype occurs between day 14.5 and birth. Received: 5 June 1998 / Revised: 20 January 1999     

Preimplantation embryo development (<Emphasis Type="Italic">Ped</Emphasis>) gene copy number varies from 0 to 85 in a population of wild mice identified as <Emphasis Type="Italic">Mus musculus domesticus</Emphasis>

The preimplantation embryo development (Ped) gene regulates the rate of preimplantation embryonic cleavage division and subsequent embryo survival. In the mouse, the Ped gene product is Qa-2 protein, a nonclassical MHC class I molecule encoded by four tandem genes, Q6/Q7/Q8/Q9. Most inbred strains of mice have all four genes on each allelic chromosome, making a total of eight Qa-2 encoding genes, but there are a few strains that are missing all eight genes, defining a null allele. Mouse strains with the presence of the Qa-2 encoding genes express Qa-2 protein and produce embryos with a faster rate of preimplantation embryonic development and a greater chance of embryo survival compared to mouse strains with the null allele. There is extensive evidence that the human homolog of Qa-2 is HLA-G. HLA-G in humans, like Qa-2 in mice, is associated with enhanced reproductive success. The human population is an outbred population. Therefore, for a better comparison to the human population, we undertook an investigation of the presence of the genes encoding Qa-2 in an outbred population of mice. We used Real-Time Quantitative PCR to quantify the number of Qa-2 encoding genes in a population of 32 wild mice identified as Mus musculus domesticus both by morphologic assessment and by PCR analysis of their DNA. We found great variability in the number of Qa-2 encoding genes in the wild mice tested. The wild mouse with the highest number of Qa-2 encoding genes had 85 such genes, whereas we discovered one wild mouse without any Qa-2 encoding genes. Evolutionary implications of a range of Qa-2 encoding gene numbers in the wild mouse population are discussed, as well as the relevance of our findings to humans.     

The Locus Encoding αa-Crystallin Is Closely Linked to H-2K on Mouse Chromosome 17

We have used a complementary DNA (cDNA) for mouse alpha A-crystallin to probe genomic DNA for restriction fragment length polymorphisms which could be used to map the alpha A-crystallin gene locus (Acry-1) in the mouse genome. Ten of 12 restriction endonucleases produced fragment polymorphism among various inbred strains of mice. A comprehensive strain survey conducted with six endonucleases resulted in the discovery of six allelic forms of Acry-1. Linkage analysis was conducted on DNA from three sets of recombinant inbred strains of mice and demonstrated close linkage of Acry-1 with the major histocompatibility complex (H-2) on chromosome 17. Analysis of congenic and recombinant congenic strains of mice confirmed the linkage of Acry-1 and H-2 and located the alpha A gene to the region between glyoxylase (Glo-1) and H-2K.     

Differential expression of alloantigens of the major histocompatibility complex on unfertilized and fertilized mouse eggs

Mouse oocytes at the dictyate and metaphase II stages as well as fertilized eggs have been studied by indirect immunofluorescence for the expression of H-2 histocompatibility antigens on surface membranes. Serologically specific reactivity to H-2 antibody was observed as patchy fluorescence distributed over the surface of the oocyte membrane. In contrast, one-cell zygotes exhibited variable reactivity, and early two-cell stages were negative. Absorption studies confirmed the serologic specificity of the reactivity on oocytes, which could be shown to be due to H-2 antibody. The results suggest that fertilization results in altered expression of major histocompatibility complex surface antigens, and confirms earlier studies that cleavage stage mouse embryos are not reactive with H-2 antibody.     

Several Galactosyltransferase Activities Are Associated with Mouse Chromosome 17

Indirect evidence suggests that some major histocompatibility complex (MHC) proteins are glycosyltransferases. No sequence or mapping information is available for transferases, although ganglioside variations in mice are linked to the H-2 complex on chromosome 17, and one galactosyltransferase activity on mouse sperm varies with T/t complex genotypes, also on chromosome 17. In the present experiments, diploid and trisomy 17 mouse embryos were assayed for four different galactosyltransferase activities. The same preparations were assayed for isocitrate dehydrogenase (Id-1, chromosome 1) and glyoxalase-1 (Glo-1, chromosome 17). Galactosyltransferase specific activities in trisomy 17 embryos are almost 1.5 times higher than in diploid embryos. The correlation between galactosyltransferase activities and chromosome 17 dosage indicates that the structural or regulatory gene for these enzymes are located on chromosome 17.     

PKA-regulated phosphorylation status of S149 and S321 sites of CDC25B inhibits mitosis of fertilized mouse eggs

To further test whether protein kinase A (PKA) can affect the mitotic cell cycle, one-cell stage mouse embryos at S phase (22 h after hCG injection) were incubated in M16 medium containing various concentrations of H-89, a PKA inhibitor. With increasing concentrations of H-89 (0-50 μmol/L), the G(2) phase of eggs was decreased and the cleavage rate was accelerated. A concentration of 40 μmol/L H-89 led to all of the mouse eggs entering the M phase of mitosis. Furthermore, to study the role of PKA in regulating the phosphorylation status of S149 and S321 sites of cell division cycle 25B (CDC25B) on one-cell stage fertilized mouse eggs, pBSK-CDC25B-WT, pBSK-CDC25B-S149A, pBSK-CDC25B-S321A and pBSK-CDC25B-S149A/S321A were transcribed into mRNAs in vitro, then mRNAs were microinjected into S phase of mouse fertilized eggs and cultured in M16 medium pretreated with H-89. Then, the cleavage of fertilized eggs, maturation promoting factor (MPF) activity and phosphorylation status of CDC2-Tyr15 were observed. In the presence of 40 μmol/L H-89, the cleavage rate of fertilized eggs in CDC25B-S/A-mRNAs and CDC25B-WT-mRNA injected groups was significantly higher than that in the control groups, and the peak of MPF activity appeared in the CDC25B-S/A-mRNAs and CDC25B-WT-mRNA injected groups earlier than that in the control groups. CDC2-Tyr15 phosphorylation state was consistent with MPF activity. In conclusion, the present study suggests that PKA regulates the early development of mouse embryos by phosphorylation of S149 and S321 of CDC25B, which plays an important role in the regulation of G(2)/M transition in the mitotic cell cycle of fertilized mouse eggs.     

A new cytotoxic lymphocyte-defined antigen coded by a gene closely linked to the H-3 locus

F1 complementation results indicate that a new gene, putatively controlling a minor histocompatibility antigen, is closely linked to the minor histocompatibility gene, H-3, in the fifth linkage group of chromosome 2 of the mouse. This gene controls a product that was capable of inducing as well as acting as a target for cytotoxic lymphocytes (CTL). The lytic activity of CTL developed in B10.LP-H-3D mice specific for the product of the new gene of B10 was restricted to target cells possessing H-2Db antigens. This contrasts to the H-2Kb-restricted activity of H-3.1 specific CTL.