Radiosensitivity variation during the cell cycle in pronuclear mouse embryos in vitro

Abstract. The radiosensitivity of pronuclear mouse (B6D2 F1 x ICR) embryos has been measured in vitro as a function of time during the cell cycle. This was done by measuring the dose of X-rays (LD50) required to prevent development of 50% of the pronuclear embryos to the blastocyst stage in 5 days of culture. The LD50 was found to vary from 1 to 2 Gy during the period from G1 to the first cleavage. The cell cycle in the pronuclear embryo was analysed by [³H]thymidine autoradiography. Compared with earlier studies on two-cell mouse embryo radiosensitivity, the pronuclear embryos appear to be more sensitive to radiation than the two-cell embryos. If, however, one considers the radiation sensitivity on a blastomere basis, the pronuclear embryos are not different in their radiation sensitivity from the two-cell embryos. Thus, during the early cleavage stages of mice, radiosensitivity is mainly governed by the content of cells of various cell cycle ages in the embryo.     

Deficiency in the response to DNA double-strand breaks in mouse early preimplantation embryos

DNA double-strand breaks (DSBs) are caused by various environmental stresses, such as ionizing radiation and DNA-damaging agents. When DSBs occur, cell cycle checkpoint mechanisms function to stop the cell cycle until all DSBs are repaired; the phosphorylation of H2AX plays an important role in this process. Mouse preimplantation-stage embryos are hypersensitive to ionizing radiation, and X-irradiated mouse zygotes are arrested at the G2 phase of the first cell cycle. To investigate the mechanisms responding to DNA damage at G2 in mouse preimplantation embryos, we examined G2/M checkpoint and DNA repair mechanisms in these embryos. Most of the one- and two-cell embryos in which DSBs had been induced by gamma-irradiation underwent a delay in cleavage and ceased development before the blastocyst stage. In these embryos, phosphorylated H2AX (gamma-H2AX) was not detected in the one- or two-cell stages by immunocytochemistry, although it was detected after the two-cell stage during preimplantation development. These results suggest that the G2/M checkpoint and DNA repair mechanisms have insufficient function in one- and two-cell embryos, causing hypersensitivity to gamma-irradiation. In addition, phosphorylated ataxia telangiectasia mutated protein and DNA protein kinase catalytic subunits, which phosphorylate H2AX, were detected in the embryos at one- and two-cell stages, as well as at other preimplantation stages, suggesting that the absence of gamma-H2AX in one- and two-cell embryos depends on some factor(s) other than these kinases.     

Nuclear accumulation of cyclin B1 in mouse two-cell embryos is controlled by the activation of Cdc2

In the present study, the sequential expression and cellular localization of cyclin B1 was examined in two-cell mouse embryos to elucidate the mechanism of the two-cell block. One-cell embryos derived from in vitro fertilization were cultured with oviductal tissue (nonblocking condition) or without oviductal tissue (blocking condition) to establish the experimental conditions in which the embryos either overcome the two-cell block or do not. The amount of cyclin B1 gradually increased through the second cell cycle (through S to G2 phase). However, the difference was not observed between culture conditions. This showed that even embryos exhibiting the two-cell block normally synthesize cyclin B1 through the cell cycle. Cyclin B1 in embryos cultured under nonblocking condition accumulates in the nucleus during the transition from the G2 to the M phase, whereas that in embryos cultured in blocking condition localizes in the cytoplasm throughout the cell cycle. These data indicate that two-cell embryos cultured in blocking condition are able to normally synthesize cyclin B1 but have defects in nuclear accumulation of the protein. However, when two-cell blocked embryos were treated with okadaic acid, an activator of Cdc2 kinase, part of cyclin B1 in the embryos translocated into the nucleus. Moreover, treatment with butyrolactone I, a specific inhibitor of Cdc2 kinase, inhibits nuclear translocation of cyclin B1 in those embryos. These results suggest that Cdc2 kinase regulates the nuclear accumulation of cyclin B1 in mouse two-cell embryos.     

The effects of U.V.-light, ionizing radiation and the carcinogen N-acetoxy-2-fluorenylacetamide on the development in vitro of one- and two-cell mouse embryos.

The development of one- and two-cell mouse embryos to morula-blastula stages was followed in vitro after treatment with low doses of U.V.-light, ionizing radiation or N-acetoxy-2-fluorenylacetamide. Exposure of one-cell embryos to either radiation source 18 and 24 hours after human chorionic gonadotropin injections prevented maturation, most embryos being arrested at the one-cell stage and a few at the two-cell stage. Two-cell embryos, however, were not sensitive to low doses of either U.V. or X-irradiation and developed normally. Treatment of early one-cell embryos with the carcinogen, N-acetoxy-2-fluorenyl-acetamide (0-7 muM), also arrested development, whereas exposure of late one-cell embryos did not completely prevent maturation to morula-blastula stages. Exposure of two-cell embryos to the same concentration of carcinogen had no effect on their development to blastulas. Results with all three agents showed that mouse embryos at the one-cell stage are more sensitive than those at the two-cell stage, as judged by their ability to develop in vitro.     

Autonomous activation of histone H1 kinase, cortical activity and microtubule organization in one- and two-cell mouse embryos

The activation of M-phase promoting factor (MPF) in one-cell mouse embryo is independent from the nucleus. Other autonomous phenomena include the cortical activity observed at the end of the first cell cycle and the reorganization of the microtubule network. Here, we observed that the autonomous control of MPF activation is present also in two-cell mouse embryos (H1 kinase activity being higher in the first than in the second cell cycle). Moreover, the disappearance of the cortical activity in anucleated halves is observed when MPF activation takes place. The rounding up of the cytoplast and the mitotic reorganization of the microtubule network correlates with the maximum activity of H1 kinase in anucleated halves from one-cell embryos. In anucleated halves of two-cell stage blastomeres neither the cortical activity nor the microtubule reorganization were observed. The degree of activation of histone H1 kinase, and, as a consequence, the cortical activity and the microtubule reorganization, does not depend on the distribution of cyclin B. Finally, the level of cyclin B synthesis is similar in anucleated and nucleated halves derived from both one- and two-cell embryos.     

Changes in the distribution of mitochondria in mouse embryos blocked at the two-cell stage

Changes in the distribution of mitochondria in the two-cell mouse embryos preceding the developmental arrest in vitro, caused by a genetically determined "two-cell block in vitro" or genisteine treatment, were examined vitally using the mitochondrial-specific probe rhodamine 123 and conventional fluorescence microscopy. In the former case, serious disturbances in the localization of mitochondria appeared already from the middle of two-cell stage, long before the time corresponding to the 2nd cleavage division. Comparison of the behavior of mitochondria in the embryos successfully developing between the one- and two-cell stages and that in the embryos that ceased to cleave suggests that the developmental arrest was accompanied by aggregation of the mitochondria into clusters. There are many such clusters unlike in the cytoplasm of normally developing embryos. Intracellular localization of clusters observed in the genisteine-treated embryos differed radically from that observed in the embryos blocked in vitro at the two-cell stage.     

Role of glucose in cloned mouse embryo development

Cloned mouse embryos display a marked preference for glucose-containing culture medium, with enhanced development to the blastocyst stage in glucose-containing medium attributable mainly to an early beneficial effect during the first cell cycle. This early beneficial effect of glucose is not displayed by parthenogenetic, fertilized, or tetraploid nuclear transfer control embryos, indicating that it is specific to diploid clones. Precocious localization of the glucose transporter SLC2A1 to the cell surface, as well as increased expression of glucose transporters and increased uptake of glucose at the one- and two-cell stages, is also seen in cloned embryos. To examine the role of glucose in early cloned embryo development, we examined glucose metabolism and associated metabolites, as well as mitochondrial ultrastructure, distribution, and number. Clones prepared with cumulus cell nuclei displayed significantly enhanced glucose metabolism at the two-cell stage relative to parthenogenetic controls. Despite the increase in metabolism, ATP content was reduced in clones relative to parthenotes and fertilized controls. Clones at both stages displayed elevated concentrations of glycogen compared with parthenogenetic controls. There was no difference in the number of mitochondria, but clone mitochondria displayed ultrastructural alterations. Interestingly, glucose availability positively affected mitochondrial structure and localization. We conclude that cloned embryos may be severely compromised in terms of ATP-dependent processes during the first two cell cycles and that glucose may exert its early beneficial effects via positive effects on the mitochondria.     

Enzymes of glycogen metabolism and related metabolites in preimplantation mouse embryos

Preimplantation mouse embryos were individually analyzed for glycogen phosphorylase, P-glucomutase, UDPG, UTP, ATP, and the sum of other nucleotide triphosphates (i.e., GTP + CTP). UDPG changes during starvation and refeeding were also determined. Phosphorylase activity was exceedingly low at the two-cell stage and rose eightfold by the morula stage. P-glucomutase was 2000 times more active than phosphorylase in two-cell embryos and fell progressively to about half the initial level by the eight-cell stage. UDPG was highest in one-cell embryos, fell to less then 20% by the two-cell stage, then recovered to about a 35% level at later stages. The ATP to UTP ratio varied from about 5:1 at the earliest stages to about 3:1 in eight-cell and older embryos. GTP plus CTP was 50% higher than UTP at the one-cell stage but was equal to UTP or lower thereafter. The results combined with earlier data from several laboratories indicate that (1) up to the morula stage the embryo can make glycogen but has difficulty using it because of insufficient glycogen phosphorylase and (2) UDPG and glucose-6-P levels are poorly coordinated, probably due to difficulty (or control) at the UDPG pyrophosphorylase step.     

Brain and sperm cell surface antigen (NS-4) on preimplantation mouse embryos

Antiserum prepared in rabbit against 4-day-old mouse cerebellum (anti-NS-4 serum) reacts in the complement-mediated cytotoxicity test with unfertilized and fertilized mouse eggs, cleavage stage embryos, and cells of the trophoblast and inner cell mass of the mouse blastocyst. This activity is specifically removed by absorption of antiserum with adult mouse brain and epididymal sperm but not with adult liver, spleen, kidney, and thymocytes. The antiserum reacts most strongly with cells of the trophoblast and inner cell mass and, in order of decreasing reactivity, with four- to eight-cell stage embryos, zygotes, unfertilized eggs, and two-cell stage embryos.     

How does transferrin overcome the in vitro block to development of the mouse preimplantation embryo?

Transferrin promotes development of mouse embryos through the two-cell block in vitro. Uptake of transferrin into blastocysts was shown to occur by both receptor-mediated and nonspecific pathways, but neither pathway was used to a detectable extent by embryos before the eight-cell stage. Conversely, the dialysis of culture medium, non-permissive for development through the two-cell block, against a solution of transferrin rendered it capable of supporting development. It was therefore concluded that transferrin exerts its supportive effect on development in vitro via its chelating effects.     

Development of mouse embryos in vitro is affected by strain and culture medium

One-cell and two-cell embryos from three random-bred strains of mice–CF1, Dub:(ICR), and CFW (Swiss-Webster)–were cultured to the blastocyst stage in Spindle's, Earle's, Ham's F10, Whittingham's T6, or Hoppe and Pitts' medium. CFW embryos were more successful than CF1 and Dub:(ICR) embryos in developing to the blastocyst stage in all five media. Dub:(ICR) and CFW two-cell embryos showed the best development in Spindle's, Whittingham's T6, and Hoppe and Pitts', whereas CF1 two-cell embryos were most successful in developing in Hoppe and Pitts' medium. Similar results were obtained with one-cell embryos, although fewer developed to the blastocyst stage, and T6 rather than Hoppe and Pitts' medium sustained the best development of CF1 one-cell embryos. For all strains, the least successful development was in Ham's F10, but CFW embryos did show good development in this medium. In addition to the effects of various media on mouse embryo development, our results indicate that the strain of mouse used for the bioassay of media is of critical importance. Random-bred CFW (Swiss-Webster) mice are as suitable as a hybrid strain for this purpose.     

Inhibition of endoplasmic reticulum stress improves mouse embryo development

X-box binding protein-1 (XBP-1) is an important regulator of a subset of genes during endoplasmic reticulum (ER) stress. In the current study, we analyzed endogenous XBP-1 expression and localization, with a view to determining the effects of ER stress on the developmental competency of preimplantation embryos in mice. Fluorescence staining revealed that functional XBP-1 is localized on mature oocyte spindles and abundant in the nucleus at the germinal vesicle (GV) stage. However, in preimplantation embryos, XBP-1 was solely detected in the cytoplasm at the one-cell stage. The density of XBP-1 was higher in the nucleus than the cytoplasm at the two-cell, four-cell, eight-cell, morula, and blastocyst stages. Furthermore, RT-PCR analysis confirmed active XBP-1 mRNA splicing at all preimplantation embryo stages, except the one-cell stage. Tunicamycin (TM), an ER stress inducer used as a positive control, promoted an increase in the density of nuclear XBP-1 at the one-cell and two-cell stages. Similarly, culture medium supplemented with 25 mM sorbitol displayed a remarkable increase active XBP-1 expression in the nuclei of 1-cell and 2-cell embryos. Conversely, high concentrations of TM or sorbitol led to reduced nuclear XBP-1 density and significant ER stress-induced apoptosis. Tauroursodeoxycholic acid (TUDCA), a known inhibitor of ER stress, improved the rate of two-cell embryo development to blastocysts by attenuating the expression of active XBP-1 protein in the nucleus at the two-cell stage. Our data collectively suggest that endogenous XBP-1 plays a role in normal preimplantation embryonic development. Moreover, XBP-1 splicing is activated to generate a functional form in mouse preimplantation embryos during culture stress. TUDCA inhibits hyperosmolar-induced ER stress as well as ER stress-induced apoptosis during mouse preimplantation embryo development.     

Replicative advantage and tissue-specific segregation of RR mitochondrial DNA between C57BL/6 and RR heteroplasmic mice

To investigate the interactions between mtDNA and nuclear genomes, we produced heteroplasmic maternal lineages by transferring the cytoplasts between the embryos of two mouse strains, C57BL/6 (B6) and RR. A total of 43 different nucleotides exist in the displacement-loop (D-loop) region of mtDNA between B6 and RR. Heteroplasmic embryos were reconstructed by electrofusion using a blastomere from a two-cell stage embryo of one strain and an enucleated blastomere from a two-cell stage embryo of the other strain. Equivalent volumes of both types of mtDNAs were detected in blastocyst stage embryos. However, the mtDNA from the RR strain became biased in the progeny, regardless of the source of the nuclear genome. The RR mtDNA population was very high in most of the tissues examined but was relatively low in the brain and the heart. An age-related increase of RR mtDNA was also observed in the blood. The RR mtDNAs in the reconstructed embryos and in the embryos collected from heteroplasmic mice showed a different segregation pattern during early embryonic development. These results suggest that the RR mtDNA has a replicative advantage over B6 mtDNA during embryonic development and differentiation, regardless of the type of nuclear genome.     

Hypoxanthine-maintained two-cell block in mouse embryos: dependence on glucose and effect of hypoxanthine phosphoribosyltransferase inhibitors

The culture conditions under which hypoxanthine maintains a two-cell block in preimplantation mouse embryos were assessed. Hypoxanthine prevented embryo development past the two-cell stage at concentrations as low as 30 nM, and this inhibitory activity required the presence of D-glucose. The action of hypoxanthine plus D-glucose was reversed by glutamine and higher lactate. D-mannose substituted for D-glucose in supporting the inhibitory action of hypoxanthine, but L-glucose, D-fructose, and 2-deoxyglucose were much less effective. Other purine derivatives such as inosine and adenosine, but not xanthosine or uric acid, also blocked development at the two-cell stage at a concentration of 30 microM, and guanosine was inhibitory at higher doses. Assays of hypoxanthine phosphoribosyltransferase (HPRT) activity in lysates of four-cell embryos determined that the drugs 6-mercapto-9-(tetrahydro-2-furyl)-purine (MPTF) and 6-mercaptopurine (6-MP), but not 6-azauridine (6-AzaU), prevented salvage of hypoxanthine. In addition, MPTF and 6-MP produced a significant two-cell block, which did not depend upon the presence of hypoxanthine or D-glucose; whereas 6-AzaU was without effect. When embryos were cultured 2 days in the presence or absence of D-glucose, hypoxanthine salvage was significantly reduced in lysates of four-cell embryos exposed to D-glucose. D-glucose had no effect when added directly to the assay mixture. These data demonstrate that the ability of hypoxanthine to block embryo development at the two-cell stage depends on the presence of D-glucose or other glycolyzable sugars and suggest that inhibition of the purine salvage pathway promotes the two-cell block.     

Cyclin A2 is phosphorylated during the G2/M transition in mouse two-cell embryos

In the present study, we investigated the expression of cyclin A2 in mouse two-cell embryos to elucidate the role of cyclin A2 at the G2/M transition. Two forms of cyclin A2 on SDS-PAGE (an upper and a lower band) were detected in two-cell embryos synchronized at the M phase by nocodazole. To investigate the nature of this shift, embryos synchronized at the M phase were treated with alkaline phosphatase (AP). The upper band of cyclin A2 was fainter in AP-treated embryos than in nontreated embryos. This result indicates that cyclin A2 in mouse two-cell embryos is phosphorylated and the band on SDS-PAGE shifts up during the G2/M transition. In addition, we examined the sequential expression of cyclin A2 in two-cell blocked embryos after OA treatment. The upper band of cyclin A2 was first detected at 2 hr after the treatment, corresponding to the timing of Cdc2 kinase activation. In two-cell embryos after removal from nocodazole treatment, the phosphorylated form of cyclin A2 protein decreased abruptly just before cytokinesis. These results suggest that the mechanism of cyclin A2 degradation in mouse two-cell embryos may be different from that in somatic cells.     

小鼠母源因子对早期胚胎发育的影响

在脊椎动物中发育过程中,卵母细胞要经历MII期停滞、受精、早期胚胎发育的启动、胚胎基因组的转录激活、并指导完成个体的发育过程。同时,核移植过程中,分化的细胞核在去核的卵母细胞中能够重编程到胚胎早期的状态并能完成个体的发育过程。在这些发育过程中母源因子都发挥了极其的重要作用。在小鼠胚胎发育研究中发现,小鼠的基因组激活发生在2细胞期,这一时期标志着合子的发育由卵母细胞控制向胚胎控制的过渡,期间发生一系列复杂的生化过程。体外培养的小鼠的胚胎的发育阻断也易发生的2细胞时期。因此对卵母细胞及早期胚胎母源因子的研究,将有利于了解早期体外培养胚胎和克隆胚胎发育失败的原因,为提高体外培养和克隆胚胎发育的成功率提供理论的基础。     

Development of hamster two-cell embryos in the isolated mouse oviduct in organ culture system

Hamster early two-cell embryos developed to the expanded blastocyst stage within the isolated mouse ampulla maintained in organ culture system. Mouse ampullae isolated at different times after treating the mice with human chorionic gonadotropin (hCG) (0–72 h) or pregnant mare's serum gonadotropin (PMSG) (30–32 h) were flushed with culture medium, and hamster early two-cell embryos were introduced into these ampullae. Mouse ampullae isolated at 14–32 h after hCG injection were more favorable for the development of the embryos than those isolated at 70–72 h. When mouse ampullae were isolated 30–32 h after hCG or PMSG treatment, 39% of the cultured eggs developed, some of them to the expanded blastocyst stage after additional culture for 65–70 h. These results indicate that unknown oviductal factors stimulate the development of hamster early two-cell embryos, and these factors are under the control of hCG or PMSG. In addition, these factors are common to the mouse and hamster.