Immunochemical differentiation of glucose phosphate isomerase (GPI) allozymes of the mouse

Polyclonal xenoantisera against mouse GPI-1B and GPI-1C were produced in rabbits and analyzed for their ability to recognize allozyme-specific determinants. These studies showed a high degree of serological similarity among the three allozymes of mouse glucose phosphate isomerase (GPI). However, GPI-1B and GPI-1C could be differentiated from GPI-1A as well as GPI-1A and GPI-1B from GPI-1C using quantitative solid-phase immunobinding assays. In addition, polyclonal and monoclonal alloantibodies specific for GPI-1C were produced in BALB/c (Gpi-1a/Gpi-1a) mice. As indicated by immunoblotting data, the allozyme specificity of rabbit antisera and monoclonal alloantibodies against GPI-1C is dependent on the native structure of that allozyme.     

Genetic differences in glucose phosphate isomerase activity among mouse embryos

We have compared mouse embryos of three heterozygous, congenic genotypes (with high, medium and low levels of oocyte-coded glucose phosphate isomerase (GPI-1) activity respectively) to test whether 1) the survival time of oocyte-coded GPI-1 activity in the early embryo is affected by its activity level in the oocyte and 2) whether embryo-coded GPI-1 is detected earlier in embryos that inherit low levels of oocyte-coded GPI-1. The oocyte-coded GPI-1 was entirely GPI-1A allozyme in the high and medium groups but was the less stable GPI-1C allozyme in the low group. We determined total GPI-1 activity and the ratio of different GPI-1 allozymes in early embryos and calculated the activity of oocyte-coded and embryo-coded GPI-1. In all three groups, the oocyte-coded enzyme activity remained at a more or less constant level for the first 21 1/2 days. Some oocyte-coded GPI-1 remained in 4 1/2 day embryos from the high and medium groups but was gone by 5 1/2 days. Very little remained in 4 1/2 day embryos that inherited low levels of a less stable form of the enzyme (GPI-1C allozyme). Despite a 4- to 5-fold difference in initial oocyte-coded GPI-1 activity, no differences were seen among the three genotypically distinct groups of embryos in the time of activation of the embryonic Gpi-1s genes. The embryo-coded GPI-1 was first detectable in 3 1/2 day compacted morulae in all three groups. The level of oocyte-coded GPI-1, in the high group, when embryo-coded GPI-1 was first detected was higher than the level in the low group at any stage prior to detection of embryo-coded GPI-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Death of mouse embryos that lack a functional gene for glucose phosphate isomerase

A null allele of the Gpi-1s structural gene, that encodes glucose phosphate isomerase (GPI-1; E.C. 5.3.1.9), arose in a mutation experiment and was designated Gpi-1sa-m1H. The viability of homozygotes has been investigated. No offspring homozygous for the null allele were produced by intercrossing two heterozygotes, so the homozygous condition was presumed to be embryonic lethal. Embryos were produced by crossing Gpi-1sa/null heterozygous females and Gpi-1sb/null heterozygous males. Homozygous null embryos were identified at different stages of development by electrophoresis and staining either for GPI-1 alone or GPI-1 plus phosphoglycerate kinase (PGK) activity. At 6 1/2 and 7 1/2 days post coitum homozygous null embryos were present at approximately the expected 25% frequency (37/165; 22.4% overall) although at 7 1/2 days the homozygous null embryos tended to be small. By 8 1/2 days most homozygous null embryos were developmentally retarded and had not developed significantly further than at 7 1/2 days; some were dead or dying. By 9 1/2 days the homozygous null conceptus was characterised by a small implantation site that contained trophoblast and often a small amount of extraembryonic membrane. Surviving trophoblast tissue was also detectable at 10 1/2 days. Previous studies have shown that oocyte-coded GPI-1 persists only until 5 1/2 or 6 1/2 days. Survival of homozygous null embryos to 7 1/2 or 8 1/2 days and survival of certain extraembryonic tissue to 10 1/2 days suggests that the homozygous null condition may not be cell-lethal although it is certainly embryo-lethal. Mutant cells that are deficient in glycolysis may use the pentose phosphate shunt to bypass the block in glycolysis created by the deficiency of glucose phosphate isomerase, and/or might be rescued by the transport, from the maternal blood, of energy sources other than glucose (such as glutamine). Either strategy may only permit slow cell growth that would not be adequate to support normal embryogenesis. Transport of maternal nutrients would be more efficient to the trophoblast and extraembryonic membranes and this may help to explain why these tissues survive for longer than the embryo itself. The morphological similarity between homozygous nulls and androgenetic conceptuses, where the trophoblast also survives better than the embryo, is discussed.     

Expression of glucose phosphate isomerase in interspecific hybrid (Mus musculus x Mus caroli) mouse embryos.

Hybrid Mus musculus x Mus caroli embryos were produced by inseminating M. musculus (C57BL/OlaWs) females with M. caroli sperm. Control M. caroli embryos developed more rapidly than did control M. musculus embryos and implanted approximately 1 day earlier. At 1 1/2 days, both the hybrid embryos and those of the maternal species (M. musculus) had cleaved to the 2-cell stage. By 2 1/2 days some of the hybrids were retarded compared to M. musculus, and by 3 1/2 days most were lagging behind. This is consistent with the idea that the rate of development of hybrid embryos declines once it becomes dependent on embryo-coded gene products. We have used this difference in rate of preimplantation development, between hybrid and M. musculus embryos, to try to determine whether the activation of embryonic Gpi-1s genes, that encode glucose phosphate isomerase (GPI-1), is age-related or stage-related. In control M. musculus embryos (both mated and Al groups), the GPI-1AB and GPI-1A allozyme, indicative of paternal gene expression, were detected in 7 of 9 samples of 3 1/2-day compacted morula stage embryos and were seen in all 19 samples of 3 1/2-day blastocysts. In hybrid embryos, these allozymes were detected 1 day later. They were not detected in any 3 1/2-day samples (12 samples of compacted morulae) but were consistently detected at 4 1/2 days (4 samples of blastocysts and 2 samples of uncompacted morulae). Our interpretation of the results is that gene activation in hybrid embryos is stage-specific, rather than age-specific, and probably begins around the 8-cell stage, with detectable levels of enzyme accumulating later. Analysis of GPI-1 electrophoresis indicated that both the paternal (M. caroli) and maternal (M. musculus) Gpi-1s alleles were equally expressed in hybrid embryos and that the paternally derived allele was not activated before the maternally derived allele.     

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.     

Early development and X-chromosome inactivation in mouse parthenogenetic embryos.

Early development and X-chromosome inactivation were studied in ethanol-induced mouse parthenogenones. About 24% of oocytes transferred to 0.5-day pseudopregnant recipients successfully implanted. However, only 49%, 20%, and 16% of implanted parthenogenones survived 5, 6, and 7 days later, respectively. Abnormal development was evident in every parthenogenone as early as 5 days after activation with the degenerating polar trophectoderm. These embryos were destined to become either small disorganized embryos or embryonic ectoderm vesicles bounded by the visceral endoderm. Only 2 of 51 representative 6- to 8-day parthenogenones sectioned had morphology of the normal egg cylinder, although growth retardation was evident. Spontaneous LT/Sv parthenogenones shared similar morphological features. In late blastocysts, the frequency of cells with an apparently inactivated X chromosome was lower in parthenogenones than in fertilized embryos. The failure of X-inactivation in the trophectoderm seems to contribute to the defective development of parthenogenones.     

Developmental kinetics of bovine nuclear transfer and parthenogenetic embryos

Early developmental kinetics of nuclear transfer (NT) embryos reconstituted with blastomeres and parthenogenones produced by ionophore activation followed by either dimethylaminopurine (DMAP) or cycloheximide (CHX) treatment was studied. In vitro produced (IVP) embryos served as controls. Embryos were cultured to the hatched blastocyst stage, and images were recorded every 0.5 h throughout the culture period. The longest cell cycle shifted from 4th to 5th cycle (26 +/- 4 and 44 +/- 5 h) in NT-embryos compared to IVP-embryos (41 +/- 2 and 20 +/- 3 h) and showed greater asynchrony between blastomeres than any other embryo category. Compared to DMAP, CHX prolonged the 1(st) (23 +/- 1 vs. 33 +/- 1 h) and shortened the 3(rd) cell cycle (17 +/- 2 vs. 13 +/- 1 h). Moreover, though cytoskeleton activity was initialised, a larger proportion of CHX embryos was unable to accomplish first cleavage. The parthegenones differed from IVP embryos with respect to the lengths of the 1st, 3rd, and 4th cell cycles and time of hatching. The findings are discussed in relation to known ultrastructural, chromosomal and genomic aberrations found in NT embryos and parthenogenones. We hypothesize that the shift of the longest cell cycle in NT embryos is associated with a shift in the time of major genomic transition.     

High activity of an unstable form of glucose phosphate isomerase in the mouse

Quantitative electrophoretic studies of the three allozymes of glucose phosphate isomerase (GPI-1) produced byGpi-1s ^a/Gpi-1s^c heterozygous mice revealed two opposing influences on GPI-1 activity. First, the GPI-1 AC heterodimer is less stable than GPI-1 AA but more stable than the GPI-1 CC homodimer. Second, a genetic determinant that maps close to or within theGpi-1s structural gene causes elevated activity of GPI-1 AC and probably also GPI-1 CC dimers. The relative lability of these allozymes masks this elevated activity in some tissues but the effect is probably ubiquitous. The significance of these observations is discussed.This study was begun while JDW was at the MRC Radiobiology Unit and continued at the Department of Obstetrics and Gynaecology of the University of Edinburgh, where it was supported, in part, by a grant from the Moray Endowment Fund.     

Subnormal zona pellucida change in parthenogenetic mouse embryos

Parthenogenetic mouse embryos were obtained by the method of electrical stimulation of eggs in vivo(Tarkowski et al., 1970), and their developmental retardation and limited viability were confirmed. Very early deviations from normalcy seemed likely in these embryos, and we chose to investigate their “zona reaction,” as this is one of the earliest events identified (Braden, et al., 1954) in normal fertilization. The change, ordinarily triggered by sperm penetration of the egg, decreases the permeability of the zona pellucida to supernumerary sperms, and has been attributed (Austin and Braden, 1956) to products released by cortical granules.An indirect assay for the state of the zona pellucida is presented. It is based on the observation (Mintz, 1970) that pronase, other proteolytic enzymes, and the normal uterine zonalytic factor lyse zonas of fertilized eggs more slowly than those of unfertilized eggs. Comparative zona lysis times in pronase are thus employed as a test for the degree of zona change after parthenogenetic activation relative to that after activation by sperm.The zonas of parthenogenetic embryos in stages ranging from 2 to 14 cells varied in their lysis times in pronase and overlapped with those of unfertilized and fertilized egg zonas. As a population, the zonas of the parthenogenones had intermediate lysis times. Thus, in the strains tested, electrical shock evokes only a partial zona reaction and, in this respect, is not an adequate substitute for sperm penetration.A working hypothesis for future testing is that the subnormal zona change and retarded development may both be due to inadequate release of products from cortical granules, under these conditions of artificial activation of the mouse egg.     

小鼠四倍体早期胚胎基因组甲基化模式

利用小鼠抗5-甲基胞嘧啶(5MeC)单克隆抗体检测了体外培养小鼠四倍体早期胚胎的基因组甲基化模式。结果表明: 利用电融合方法制备的小鼠四倍体胚胎在体外培养体系中经历细胞质融合、细胞核融合及细胞继续分裂发育直到囊胚期的过程, 在细胞质融合的时候胚胎卵裂球同体内体外培养二倍体胚胎一样, 呈现高度甲基化状态; 在细胞核开始融合的时候, 甲基化水平急速下降, 在细胞核完全融合的时候甲基化水平达到最低点; 随着胚胎继续分裂, 胚胎甲基化水平逐渐增加, 在桑葚胚期甲基化水平最高; 但是囊胚期四倍体胚胎内细胞团同滋养层细胞甲基化荧光信号没有差别, 这与体内体外培养二倍体囊胚内细胞团细胞甲基化荧光强度高于滋养层细胞甲基化荧光强度不同。因此, 小鼠体外培养四倍体胚胎的甲基化模式是不正常的, 这可能是四倍体小鼠难以发育到妊娠足月的原因之一。这是对小鼠四倍体早期胚胎基因组甲基化模式的首次报道。     

小鼠胚胎干细胞与四倍体胚胎的嵌合

The oviducts of superovulated Kunming white females were flushed 44-46 hours after treatment with human chorionic gonadotropin to collect 1074 late two-cell-stage embryos.The embryos were placed twenty at a time between two platinum electrodes laid 1 mm apart in 0.3M mannitol in the electrode chamber.The blastomeres were fused by a short electric pulse(80V for 50μsec) applied by a pulse generator.Fusion of blastomeres was usually completed in 20-60minutes.After 25 hours of culture,most of the tetraploid embryos developed to the four-cell stage.Zonae pellucidae of 387 four-cell-stage tetraploid embryos were removed by treatment with acid Tyrode‘s buffer.The embryos were plated on an ES cell layer,After 40 hours of coculture,248 embryos aggregated with ES cells were collected and transferred into the uteri of twenty four 2.5-day pseudopregnant recipinets.Ten recipients were pregnant.but no live fetuses were born.Three pregnant recipients were routinely subject to a Caesarean section on day 18 of pregnancy and seven abnormal fetuses were obtained.The results demonstrate that ES cells derived from C57BL/6 mice are pluripotential to a certain extent.     

Sex-chromosome constitution of postimplantation tetraploid mouse embryos

Tetraploid mouse embryos were produced at the two-cell stage by blastomere fusion induced by inactivated Sendai virus. The embryos were from chromosomally normal female mice that had been fertilised by homozygous Rb(1.3)1Bnr males carrying a pair of large metacentric marker chromosomes in their karyotype. These "reconstructed" one-cell tetraploid embryos were then transferred to the oviducts of pseudopregnant recipients, which were subsequently autopsied early on the 10th day of gestation. Two-cell stage embryos that did not undergo blastomere fusion after 4-5 h were transferred to a second group of recipients, which were also autopsied early on the 10th day of gestation. From a total of 153 tetraploid embryos transferred to females that subsequently became pregnant, 135 implanted. Sixty-eight implantation sites were found to contain resorptions, whereas 67 contained mostly headfold presomite-stage embryos. Four embryos possessed four to six pairs of somites. All 57 embryos that could be analysed cytogenetically were found to be tetraploid. G-banding analysis revealed that 30 of these embryos had an XXYY and 27 and XXXX sex-chromosome constitution. The presence of two marker chromosomes in all mitotic preparations from each of these tetraploid embryos confirmed that they had all been produced by duplication of their original XY or XX diploid chromosome constitution, respectively. The XXYY:XXXX sex ratio observed was not significantly different from unity. In the control series of transfers, all of the embryos recovered were at the forelimb bud stage and had a diploid chromosome constitution. The results reported here differ from human clinical findings, in which the XXYY:XXXX sex ratio of 120 human tetraploid spontaneous abortions recovered over the last 20 years is 45:75. Possible explanations for these differences are briefly discussed.     

Transient reactivation of CSF in parthenogenetic one-cell mouse embryos

During meiosis, the cytostatic factor (CSF) activity stabilizes the activity of the M-phase promoting factor (MPF) in metaphase II arrested vertebrate oocytes. Upon oocyte activation, the inactivation of both MPF and CSF enables the entry into the first embryonic mitotic cell cycle. Using a biological assay based on cell-fusion (hybrid between a parthenogenetically activated egg entering the first mitotic division and an activated oocyte), we observed that in activated mouse oocytes a first drop in CSF activity is detectable as early as 20 min post-activation. This suggests that CSF is inactivated upon MPF inactivation. However, CSF activity increases again to reach a maximum 60 min post-activation and gradually disappears during the following 40 min. Thus, in activated mouse oocytes (undergoing the transition to interphase) CSF activity fluctuates before definitive inactivation. We found that hybrids arrested in M-phase, thus containing CSF activity after oocyte activation, have activated forms of MAP kinases while hybrids in interphase have inactive forms of these enzymes. We postulate that CSF inactivation in mouse oocytes proceeds in two steps. The initial inactivation of CSF, required for MPF inactivation, is transient and does not require MAP kinase inactivation. The final inactivation of CSF, required for normal embryonic cell cycle progression, is dependent upon the inactivation of MAP kinases.     

The first cycle of DNA replication in parthenogenetic mouse embryos

Dynamics of the first cell cycle in parthenogenetic mouse embryos derived from ethanol-activated eggs was studied using 3H-thymidine. DNA synthesis starts within 5 h and is terminated within 10 h after activation: it lasts ca. 6 h. Changes in the intensity of 3H-thymidine incorporation and in the distribution of radioactive label between haploid and diploid parthenogens were observed. 3H-thymidine was shown to incorporate into pronucleoli of diploid parthenogens and late-labeled heterochromatin blocks were bound in both diploid and haploid pronuclei. The structure of the first cell cycle in parthenogenetic and normal embryos is discussed.     

Functional analysis of trophoblast giant cells in parthenogenetic mouse embryos

Diploid mouse embryos containing only maternal DNA (parthenotes) fail, in part, because the inner cell mass does not induce the trophoblast to grow. In this study, we asked whether any of the defects in parthenotes may arise from alterations in trophoblast function. We examined the expression of genes important for normal trophoblast function and found several trophoblast genes that were expressed at normal levels in the primary trophoblast cells of parthenotes: E-cadherin, a cell adhesion molecule, was expressed normally in both the ICM and trophectoderm of parthenogenetic blastocysts and blastocyst outgrowths; the gene for Hxt, a basic helix-loop-helix factor that regulates trophoblast development, was expressed in both zygotic and parthenogenetic giant cells; placental lactogen-1, a hormone that is normally secreted by trophoblast giant cells, was expressed in most of both parthenogenetic and normal trophoblast cells; and the 92 kDa matrix metalloproteinase, gelatinase B, also known as MMP-9, was secreted at equivalent levels by both zygotic and parthenogenetic blastocyst outgrowths. However, once the outgrowths had developed, a subpopulation of trophoblast cells in parthenogenetic embryos had decreased DNA replication and significantly fewer nucleoli per nucleus than did zygotic embryos. Moreover, the parthenogenetic trophoblast cells growing out from blastocysts had a decreased viability in culture. These data suggest that, although parthenogenetic embryos are able to initiate primary trophoblast differentiation, the stability and continued differentiation of trophoblast giant cells may be abnormal. Our data support the hypothesis that the deficiency of secondary trophoblast giant cells may contribute to the decline of parthenogenetic embryos and suggest that the factors controlling this subset of trophoblast are distinct from those for primary trophoblast. Dev Genet 20:1–10, 1997. © 1997 Wiley-Liss, Inc.     

Cotransfer of parthenogenetic embryos improves the pregnancy and implantation of nuclear transfer embryos in mouse

The majority of somatic cell nuclear transfer (SCNT) clones dies in the peri- or postimplantation period. Improvement of the full-term healthy pregnancy rates is a key issue for the economical viability and animal welfare profile of SCNT technology. In this study the effects of cotransfer of parthenogenetic or fertilized embryos on the pregnancy and implantation of SCNT mouse embryos have been investigated. SCNT embryos were produced by transferring cumulus cell nuclei into enucleated B6D2F1 mouse oocytes, whereas parthenogenetically activated (PA) and fertilized embryos were derived from ICR mice by artificial activation with strontium and in vivo fertilization, respectively. SCNT embryos were inferior in their developmental capacity to blastocyst compared to either PA or fertilized embryos. SCNT embryos were transferred alone (SCNT), or cotransferred with two to three PA (SCNT + PA) or fertilized (SCNT + Fert) embryos into the oviducts of an ICR recipient. Both pregnancy and implantation rates originating from clones in the SCNT + PA group were significantly higher than those of SCNT group (p < 0.05). The weight of placentas of clones derived from SCNT, SCNT + PA, or SCNT + Fert was in all cases significantly higher than that of fertilized controls (p < 0.001). Most of the clones derived from SCNT embryos cotransferred with PA or fertilized embryos survived to adulthood and were fertile and healthy according to histopathological observations. Our results demonstrate in mouse that cotransfer of PA embryos improves the pregnancy and implantation of SCNT embryos without compromising the overall health of the resulting clones.