Expression of major histocompatibility complex class I proteins and their antigen processing chaperones in mouse embryonic stem cells from fertilized and parthenogenetic embryos.

Embryonic stem (ES) cells are pluripotent cells with the potential to differentiate into cells or tissues that may be used for transplantation therapy. Parthenogenetic ES (pES) cells have been recently derived from both mouse and human oocytes and hold promise as a cell source that is histocompatible to the oocyte donor. Because of the importance of major histocompatibility complex (MHC) antigens in mediating tissue rejection or acceptance, we examined levels of mRNA and protein expression of MHC class I proteins, as well as several MHC class I antigen processing and presentation chaperones in mouse ES cells derived from both fertilized (fES) and parthenogenetic (pES) embryos. We found that H-2K, Qa-2, TAP1, TAP2, and tapasin mRNAs were all expressed at low levels in undifferentiated and differentiating ES cells and were significantly upregulated in response to interferon-gamma (IFN-gamma) treatment following 14 days of differentiation. Likewise, expression of H-2K(b) and H-2K(k) proteins were upregulated to detectable levels by IFN-gamma after 14 days of differentiation, but Qa-2 protein expression remained low or absent. We also found that MHC class I, TAP1, TAP2, and tapasin mRNAs were all expressed at very low levels in ES cells compared with T cells, suggesting transcriptional regulation of these genes in ES cells. Calnexin, a chaperone molecule involved in other pathways than MHC expression, had mRNA levels that were similar in ES cells and T cells and was not upregulated by IFN-gamma in ES cells. Overall, ES cells derived from fertilized embryos and parthenogenetic embryos displayed remarkably similar patterns of gene expression at the mRNA and protein levels. The similarity between the fES and pES cell lines with regard to expression of MHC class I and antigen-processing machinery provides evidence for the potential usefulness of pES cells in transplantation therapy.

Genetics and imaging to assess oocyte and preimplantation embryo health.

Two major criteria are currently used in human assisted reproductive technologies (ART) to evaluate oocyte and preimplantation embryo health: (1) rate of preimplantation embryonic development; and (2) overall morphology. A major gene that regulates the rate of preimplantation development is the preimplantation embryo development (Ped) gene, discovered in our laboratory. In mice, presence of the Ped gene product, Qa-2 protein, results in a fast rate of preimplantation embryonic development, compared with a slow rate of preimplantation embryonic development for embryos that are lacking Qa-2 protein. Moreover, mice that express Qa-2 protein have an overall reproductive advantage that extends beyond the preimplantation period, including higher survival to birth, higher birthweight, and higher survival to weaning. Data are presented that suggest that Qa-2 increases the rate of development of early embryos by acting as a cell-signalling molecule and that phosphatidylinositol-32 kinase is involved in the cell-signalling pathway. The most likely human homologue of Qa-2 has recently been identified as human leukocyte antigen (HLA)-G. Data are presented which show that HLA-G, like Qa-2, is located in lipid rafts, implying that HLA-G also acts as a signalling molecule. In order to better evaluate the second criterion used in ART (i.e. overall morphology), a unique and innovative imaging microscope has been constructed, the Keck 3-D fusion microscope (Keck 3DFM). The Keck 3DFM combines five different microscopic modes into a single platform, allowing multi-modal imaging of the specimen. One of the modes, the quadrature tomographic microscope (QTM), creates digital images of non-stained transparent cells by measuring changes in the index of refraction. Quadrature tomographic microscope images of oocytes and preimplantation mouse embryos are presented for the first time. The digital information from the QTM images should allow the number of cells in a preimplantation embryo to be counted non-invasively. The Keck 3DFM is also being used to assess mitochondrial distribution in mouse oocytes and embryos by using the k-means clustering algorithm. Both the number of cells in preimplantation embryos and mitochondrial distribution are related to oocyte and embryo health. New imaging data obtained from the Keck 3DFM, combined with genetic and biochemical approaches, have the promise of being able to distinguish healthy from unhealthy oocytes and embryos in a non-invasive manner. The goal is to apply the information from our mouse model system to the clinic in order to identify one and only one healthy embryo for transfer back to the mother undergoing an ART procedure. This approach has the potential to increase the success rate of ART and to decrease the high, and undesirable, multiple birth rate presently associated with ART.

Painting Qa-2 onto Ped slow preimplantation embryos increases the rate of cleavage.

PROBLEM: Qa-2 protein, the Ped gene product, is linked to the cell surface by a glycosylphosphatidylinositol (GPI) anchor. Some GPI-linked proteins can be spontaneously incorporated into the membranes of cells via a technique called "protein painting."We investigated whether Qa-2 could be painted onto T cells and embryos and whether the painted protein would be functional. METHOD OF STUDY: Incorporation of Qa-2 into the membranes of T cells and embryos was measured by FACScan and Immuno-PCR, respectively. Function of Qa-2 was measured by cell proliferation. RESULTS: Qa-2 was incorporated by T cells and embryos and was functional. CONCLUSION: GPI-linked Qa-2 protein "painted" onto both T cells and preimplantation embryos is functional, as shown by increased proliferation of T cells after cross-linking with anti-Qa-2 antibody, and increased rate of cleavage division of the embryos.

Analysis of mRNA levels for the MHC class I-like molecules CD1 and FcRn in preimplantation mouse embryos.

PROBLEM: Major histocompatibility complex (MHC) antigens expressed on preimplantation embryos are important for the control of development, reproduction, and allo-recognition of the embryo by the mother. Four types of MHC class I and MHC class I-like antigens have recently been defined: class Ia, class Ib, class Ic, and class Id, based on their similar three-dimensional protein structures. Class Ia and class Ib antigens are encoded in the MHC, whereas class Ic and class Id antigens are encoded by genes on other chromosomes. Both class Ia and class Ib MHC antigens are expressed on preimplantation mouse embryos. The function of the class Ia antigens on embryos is unknown, but the function of one class Ib antigen, Qa-2, the product of the Ped gene, has been found to control the rate of early cleavage division and subsequent embryo survival. The expression of class Ic and class Id antigens on preimplantation embryos has not yet been evaluated. In the present study, we report the analysis of mRNA expression of two class Id genes, CD1 and FcRn, in preimplantation mouse embryos. METHOD OF STUDY: A reverse transcription-polymerase chain reaction (RT-PCR) assay was performed to analyze mRNA levels for CD1 and FcRn in 1-cell, 2-cell, 8-cell, and blastocyst stage embryos from C57BL/6 mice. RESULTS: No expression of CD1 mRNA was found in any of the preimplantation embryos tested. As a by-product of this study, we found a mistake in the published sequence of the mouse CD1 gene: nucleotide 746 in the cDNA is a G not a C. This base change is in a site recognized by the restriction enzyme PstI, thereby eliminating a PstI cleavage site. Expression of mRNA for FcRn was found in all preimplantation stages tested. Higher levels of mRNA for FcRn were detectable in 2-cell and 8-cell embryos compared to 1-cell and blastocyst stage embryos. CONCLUSION: This study shows that mRNA for FcRn but not for CD1 is found in preimplantation mouse embryos.

Cross-linking of Qa-2 protein, the Ped gene product, increases the cleavage rate of C57BL/6 preimplantation mouse embryos.

The Qa-2 protein, a glycosylphosphatidylinositol (GPI)-linked major histocompatibility complex (MHC) Class Ib molecule found on the surface of mouse T-cells and preimplantation embryos, is the product of the preimplantation embryo development (Ped) gene. The Ped gene regulates the rate of early embryonic development and subsequent embryo survival. T-cells treated with anti-Qa-2 monoclonal antibody (mAb) and cross-linked with a secondary antibody, in the presence of a co-stimulatory signal, undergo increased proliferation. The purpose of this study was to determine whether cross-linking of Qa-2 similarly affects preimplantation embryos. We cross-linked Qa-2 protein on the surface of C57BL/6 2-cell and 8-cell embryos, in the presence of 4/5-phorbol-12-myristate-13-acetate (PMA), and assessed the percentage of embryos reaching the blastocyst stage, the percentage hatching from the zona pellucida, [(3)H-thymidine] incorporation into DNA, and the total number of cells per embryo as measures of embryonic cleavage rate. Both 2-cell and 8-cell embryos increased their cleavage rates 48 h after cross-linking of Qa-2, compared with control embryos (P < 0.05). Our results indicate that a Qa-2 protein cross-linking mechanism may be one way by which this protein regulates the rate of preimplantation mouse embryo development.

Regulation of Ped gene expression by TAP protein.

The Ped (Preimplantation embryo development) gene regulates fast or slow cleavage of preimplantation mouse embryos and their subsequent survival. The protein product of the Ped gene is the major histocompatibility complex (MHC) class Ib protein Qa-2. MHC class I expression on the cell surface requires the assembly within the endoplasmic reticulum (ER) of an alpha heavy chain, a beta2 microglobulin light chain, and a small peptide. Small peptides are primarily produced in the cytosol by the ubiquitin-proteasome pathway and then are transported into the ER by the transporter associated with antigen processing (TAP) protein. However, some peptides can bind to MHC class I heavy chains in a TAP-independent manner. In this study, we assessed whether TAP protein regulates Qa-2 expression on the cell surface of preimplantation mouse embryos thereby influencing the PED phenotype of the embryos. We chose Tap 1 knockout mice and their control mice (B6.129) as our experimental system. We analyzed Qa-2 mRNA expression by RT-PCR, total Qa-2 protein expression by Western blotting, and cell surface Qa-2 protein expression by Immuno-PCR in preimplantation embryos of both Tap 1 knockout mice and control mice. Then we determined the PED phenotype of both Tap 1 knockout mouse embryos and control mouse embryos. The results showed that Qa-2 expression on the cell surface of preimplantation embryos is dependent on TAP protein, and that Qa-2 expression on the cell surface is required for expression of the fast 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.

Expression of caspase and BCL-2 apoptotic family members in mouse preimplantation embryos.

Apoptosis, as determined by blastomere and DNA fragmentation, occurs in many preimplantation mouse embryos. To investigate which genes contribute to apoptosis in preimplantation embryos, we used the reverse transcription-polymerase chain reaction to assess mRNA levels for seven genes in the caspase family and seven genes in the BCL-2 family. All caspase mRNAs were detectable in oocytes, while expression in preimplantation embryos varied in a stage-specific manner. An assay for group II caspase enzymatic activity showed that although transcripts for these caspases could not be detected in zygotes, proteolytic activity could be detected in polar bodies, fragmented zygotes, and zygotes treated with staurosporine. This suggests that maternal caspases are inherited during oogenesis. Transcripts for some members of the BCL-2 family could be detected at every stage of preimplantation development. Transcripts for other members were rarely detected. When BCL-2 and BAX protein levels were assessed using immunofluorescence, both proteins were detected in zygotes and in blastocysts. When fragmented blastocysts were compared to normal blastocysts, levels of BCL-2 immunofluorescence tended to be lower in fragmented blastocysts. This result supports a model in which the ratio of BCL-2 to BAX is altered in apoptotic embryos.

Search for a human homologue of the mouse Ped gene.

The Ped gene influences the rate of cleavage division of preimplantation mouse embryos and subsequent embryonic survival. The mouse Ped gene product is a major histocompatibility complex (MHC) class Ib protein called Qa-2. Studies from many human in-vitro fertilization (IVF) clinics suggest that the mouse Ped gene has a human homologue because embryos fertilized at the same time have different cleavage rates, and those embryos that cleave at a faster rate are more likely to result in a viable pregnancy. Candidates for the human homologue of the mouse Ped gene include the MHC class Ib genes HLA-E, HLA-F, and HLA-G. The presence of mRNA for these three genes was tested in 108 spare day 3 human preimplantation embryos from 25 couples by using reverse transcription-polymerase chain reaction (RT-PCR). Of the 86 embryos tested for HLA-E mRNA, 72 were positive (84%), and of the 88 embryos tested for HLA-G mRNA, 39 were positive (44%). None of the 17 embryos tested for HLA-F mRNA were positive (0%). Studies of expression of HLA-G protein were undertaken to ascertain whether HLA-G was attached to the cell membrane via a glycosylphosphatidylinositol (GPI) linkage similar to that found in Qa-2 protein. Treatment of JEG-3 cells, an HLA-G expressing cell line, with phospholipase C did not result in removal of HLA-G showing that HLA-G, unlike Qa-2, is not GPI linked to the cell surface. The pros and cons of HLA-E, HLA-F, and HLA-G as candidates for the human Ped gene are discussed.

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.

The expression pattern of the Qa-2 antigen in mouse preimplantation embryos and its correlation with the Ped gene phenotype.

The Qa-2 antigen, the product of the Ped (Preimplantation embryo development) gene, is a glycosylphosphatidylinositol-linked cell surface protein encoded in the Q region of the mouse major histocompatibility complex (MHC). Ped fast (Qa-2+) mouse strains have significantly higher preimplantation embryo cleavage rates both in vivo and in vitro than Ped slow (Qa-2-) mice. In this study, we determined whether the Ped fast phenotype of blastocysts is due to an increased number of blastomeres in the trophectoderm (TE), the inner cell mass (ICM), or both. We also analysed the Ped gene expression pattern, both at the mRNA and at the protein level, in these lineages. Blastocysts were collected from the congenic mouse strains B6.K2 (Qa-2 +) and B6.K1 (Qa-2-). We performed reverse transcription-polymerase chain reaction (PCR) and Immuno-PCR and found that the Ped gene is expressed at the mRNA and protein level in whole embryos and in isolated ICM cells. Lastly, we differentially stained embryos from these strains and found that B6.K2 blastocysts had significantly higher cell numbers (P < 0.05) in both the ICM and in the TE than B6.K1 blastocysts. These results suggest that Qa-2 expression in both the TE and the ICM of blastocysts directly contributes to the Ped phenotype.

Genetic regulation of egg and embryo survival.

In both mice and humans, 15-50% of embryos die during the preimplantation period from mechanisms that are largely unknown. Two major criteria predict preimplantation embryo quality, the rate of development and the degree of fragmentation. We review evidence that both of these criteria have a genetic basis. Rate of development and subsequent embryo survival are controlled by a gene, Ped, we discovered in the mouse. Although progress is being made in the search for the human homologue of the mouse Ped gene, it has not yet been identified. Fragmentation, observed in both mouse and human embryos, is probably the result of apoptosis. We analysed transcription of two genes that regulate apoptosis, bcl-2 and bax, and found that both are transcribed in mouse and human preimplantation embryos. Overall, the literature reviewed and new data presented in this paper support the concept that there is a genetic basis for preimplantation egg and embryo survival.

Differential expression of Ped gene candidates in preimplantation mouse embryos.

The Ped (preimplantation embryonic development) gene influences the rate of mouse preimplantation embryonic development and subsequent survival. Four similar tandem genes in the Q region of the major histocompatibility complex-Q6, Q7, Q8, and Q9-were identified as Ped gene candidates. In this study, expression of these genes during preimplantation development was examined and quantitated by reverse transcription-polymerase chain reaction and single nucleotide primer extension assays in order to investigate their contribution to the Ped gene phenotype. The Q7/Q9 gene pair was found to be transcribed in preimplantation mouse embryos, whereas transcription of the Q6/Q8 gene pair was undetectable. Both Q7 and Q9 are expressed in embryos from one Ped fast strain, C57BL/6, while only the Q9 gene is expressed in another Ped fast strain, B6.K2. These results suggest that both the Q7 and Q9 genes can function as the Ped gene in the mouse. Interestingly, the expression pattern of the Q7 and Q9 genes in preimplantation embryos is the same as in splenic lymphocytes. However, the Q6 and Q8 genes are expressed in splenic lymphocytes but not in preimplantation embryos. Treatment of mouse preimplantation embryos with interferon gamma (gamma-IFN) did not induce expression of the Q6/Q8 genes but enhanced expression of the Q7/Q9 genes. The mechanism of this differential transcription pattern is currently under investigation.

Genetic regulation of preimplantation mouse embryo survival.

The preimplantation period of mammalian development is characterized by cleavage of a one-cell embryo to a blastocyst stage embryo. During preimplantation development, 15%-50% of the embryos die as a result of factors that are largely unknown. Two parameters of preimplantation development, a fast rate of development and a low degree of fragmentation, are indicative of good embryo quality. There is mounting evidence that genes control both rate of development and degree of fragmentation. We have discovered a gene, Ped (preimplantation embryo development), which controls the rate of preimplantation embryonic cleavage. The Ped gene is encoded by two similar genes, Q7 and Q9, in the Q region of the mouse major histocompatibility complex (MHC). The Ped gene product is an MHC class Ib protein, the Qa-2 antigen. The mechanisms by which the Ped gene controls rate of embryonic cleavage division are being explored. In order to understand genetic mechanisms underlying the second criterion of embryo quality, degree of fragmentation, we have begun to assess expression of the genes that could potentially regulate apoptosis in preimplantation embryos. We have shown that staurosporine can induce apoptosis in mouse blastocysts. By using RT-PCR, we have shown that genes encoding protein in the two major gene families that regulate apoptosis, the Bcl-2 and caspase gene families, are present in preimplantation embryos. We hypothesize that there is a homeostatic mechanism by which genes that regulate cell survival and those that regulate cell death determine the overall viability of preimplantation embryos.

Role of the Ped gene and apoptosis genes in control of preimplantation development.

PURPOSE: The properties of the mouse Ped gene and the genes that mediate apoptosis in mediating preimplantation embryonic survival were reviewed. METHODS: Preimplantation mouse oocytes and embryos were evaluated microscopically and biochemically for rate of development, degree of fragmentation, and gene expression to correlate these characteristics with embryo mortality, Biochemical assays included PCR for DNA analysis, RT-PCR for mRNA analysis, immuno-PCR for protein analysis, and TUNEL assay for assessment of apoptosis. RESULTS: Using the mouse as a model system we have identified a gene that controls the rate of development, the Ped gene. The Ped gene product is a class Ib major histocompatibility complex protein called the Qa-2 antigen. Research to understand the molecular mechanisms of Ped gene action and to identify the human homologue of the Ped gene is under way. We have also shown using the mouse model, that fragmented embryos show the morphological and biochemical characteristics of apoptosis. Genes in the two major gene families that regulate apoptosis, the caspase and Bcl-2 families, are expressed in mouse oocytes and preimplantation embryos. CONCLUSIONS: Preimplantation embryonic survival depends on two major morphological parameters: rate of development and degree of fragmentation. A fast rate of development and a low degree of fragmentation lead to a better chance of producing live offspring. Both rate of development and degree of fragmentation are genetically controlled, the former by the Ped gene and the latter most likely by genes that mediate apoptosis. It seems probable that regulation of apoptosis will prove to be a major mechanism that mediates oocyte and preimplantation embryonic survival.

The effect of melatonin on cleavage rate of C57BL/6 and CBA/Ca preimplantation embryos cultured in vitro.

There is growing interest in using melatonin as a therapeutic agent for the treatment of a variety of medical conditions, including cancer, heart disease, glaucoma, stress, jet lag, and sleep disorders. In addition, melatonin is being evaluated in a clinical trial to test its efficacy as an oral contraceptive. In order to test any possible adverse effects of melatonin on preimplantation embryos, we used the mouse as a model system. Two strains of mice, a Ped fast, melatonin-deficient strain, C57BL/6, and a Ped slow strain previously found to have detectable melatonin levels at nighttime, CBA/Ca, were studied. Two cell embryos were incubated with melatonin concentrations from 10(-5) M to 10(-13) M for 48 or 72 hours and the number of cells per embryo assessed quantitatively at the end of the incubation period. We used sufficiently high levels of melatonin to mimic the pharmacological concentration used in the oral contraceptive. It was found that there was no effect of melatonin on embryos from either mouse strain at any of the concentrations tested. Our results suggest that if conception occurs while melatonin is being administered to treat a range of conditions, it would not adversely affect the embryo.

Sequence and transcription of Qa-2-encoding genes in mouse lymphocytes and blastocysts.

The protein product of the mouse preimplantation embryo development (Ped) gene, which controls the rate of preimplantation embryonic cleavage division and subsequent embryo survival, is the Qa-2 antigen. This major histocompatibility complex (MHC) class I b protein is encoded by four genes, Q6, Q7, Q8, and Q9. The present study was undertaken to begin to elucidate which of the four Qa-2-encoding genes are responsible for the Ped gene phenotype in the C57BL/6 mouse (H2(b)). First, restriction maps of the four genes, using 25 restriction enzymes, were created. The RE maps confirmed that Q6 is similar to Q8 and Q7 is similar to Q9, but that the Q6/Q8 gene pair differs from the Q7/Q9 gene pair. The genomic DNA sequences of Q6 and Q8 were determined, as well as the DNA sequences of exons 4 - 8 of Q9, and the 5' regulatory regions of Q6, Q8, and Q9. This DNA sequence information, combined with the published DNA sequence information for the entire Q7 gene and exons 1 - 3 of Q9, allowed us to design primers for reverse transcription-polymerase chain reaction that could distinguish which of the four genes were transcribed in mouse lymphocytes and embryos. It was found that all four genes are transcribed in lymphocytes, but only Q7 and Q9 are transcribed in mouse embryos. Thus, both Q7 and Q9 are candidates for the genes responsible for the Ped gene phenotype.

Mapping of the SLA complex class III region by pulsed field gel electrophoresis.

The fine order of genes in the class III region of the swine major histocompatibility complex (MHC), the SLA complex, was examined by pulsed field gel electrophoresis (PFGE) and Southern blot analysis. Four genes, C2, HSP70, TNF alpha, and CYP21, were analyzed. The CYP21, C2, and HSP70 genes were all located within a 200-kb NotI fragment. The C2, HSP70, and TNF alpha genes cohybridized to a 420-kb SalI fragment. The TNF alpha gene is linked to the class I region by a 390-kb NotI fragment. Combined with a previous study from our lab, the order of genes in the SLA complex is class II-class III [(CYP21/C4)-(Bf/C2/HSP70)-TNF alpha]-class I. The size of the class III region from CYP21 to TNF alpha is estimated to be 500 kb. This size and the order of the genes in the swine class III region are similar to those of human, mouse, goat, and rabbit, which confirms the high conservation of class III gene organization across species.