Effect of polyamine limitation on DNA synthesis and development of mouse preimplantation embryos in vitro

In-vitro treatment of preimplantation mouse embryos with spermine and spermidine biosynthesis inhibitor, methylglyoxal-bis-(guanylhydrazone) (MGBG), arrested embryo development at the 8-cell or morula stage. In addition, the embryo DNA synthetic rate, as measured by [3H]thymidine incorporation, was strongly inhibited. The inhibition of blastocyst formation and DNA synthesis by MGBG was readily reversible by an exogenous supply of spermine and/or spermidine to the culture medium. DL-alpha-Methylornithine or DL-alpha-difluoromethylornithine (alpha-DFMO), inhibitors of putrescine biosynthesis, had no effect on embryos cultured for 1 or 2 days, but on the 3rd day embryo DNA synthesis was significantly depressed in the presence of alpha-DFMO. These observations suggest that, during early development of the preimplantation mouse embryo, spermine and spermidine are involved in regulation of embryo growth and DNA synthesis. They may also indicate a role of putrescine at a later stage of mouse embryo development.     

Preimplantation mouse embryos synthesize membrane sterols

The total cholesterol content of preimplantation mouse embryos increases approximately threefold (to 1 pmole) during the development of a blastocyst from a fertilized egg. From the two-cell stage onwards embryos are capable of converting [³H]mevalonate into the membrane sterols lanosterol and cholesterol. However, activity of the ratelimiting enzyme in sterol synthesis, hydroxymethylglutaryl coenzyme A reductase, was only measurable in late expanded blastocysts. These estimates of cholesterol content and the amounts of ³H-sterol formed suggest that the preimplantation mouse embryo can synthesize membrane sterols from early cleavage stages onwards. Late compaction and early fluid accumulation (approx. 84 hr post-hCG) are associated with a transition from lanosterol to cholesterol synthesis. The possible relationship between this transition and changes in the properties of embryo membranes which occur at this time is discussed. The results, taken together with previous evidence for phospholipid synthesis in early embryos, demonstrate that the preimplantation mouse embryo is capable of synthesizing major membrane lipids and hence has the potential for assembling cell membranes and modulating their lipid-mediated properties.     

Vitrification of murine mature metaphase II oocytes perturbs DNA methylation reprogramming during preimplantation embryo development

Accurate reprogramming of DNA methylation occurring in preimplantation embryos is critical for normal development of both fetus and placenta. Environmental stresses imposed on oocytes usually cause the abnormal DNA methylation reprogramming of early embryos. However, whether oocyte vitrification alters the reprogramming of DNA methylation (5 mC) and its derivatives in mouse preimplantation embryo development remains largely unknown. Here, we found that the rate of cleavage and blastocyst formation of embryos produced by IVF of vitrified matured oocytes was significantly lower than that in control counterparts, but the quality of blastocysts was not impaired by oocyte vitrification. Additionally, although vitrification neither altered the dynamic changes of 5-hydroxymethylcytosine (5hmC) and 5-formylcytosine (5 fC) before 4-cell stage nor affected the levels of 5 mC and 5-carboxylcytosine (5caC) throughout the preimplantation development, vitrification significantly reduced the levels of 5hmC and 5 fC from 8-cell stage onwards. Correspondingly, vitrification did not alter the expression patterns of Tet3 in preimplantation embryos but apparently reduced the expression levels of Tet1 in 4-cell and 8-cell embryos and increased the expression levels of Tet2 at morula stage. Taken together, these results demonstrate that oocyte vitrification perturbs DNA methylation reprogramming in mouse preimplantation embryo development.     

The role of calcium in DNA synthesis and development of mouse preimplantation embryos in vitro.

The effect of calcium upon embryonic growth was studied using cultured mouse preimplantation embryos. Both morphological development of the embryos and embryo DNA synthesis were shown to be dependent on the Ca2+ concentration in the medium in which the embryos were grown. Reduction of the calcium concentration below 10(-5) M completely blocked cell division and blastocyst formation in the cultured embryos, but only moderately inhibited embryo DNA synthesis. Trifluoperazine, a calmodulin antagonist, strongly inhibited the Ca(2+)-dependent DNA synthesis in the embryos. On the other hand, the drug only slightly affected the morphological development of the embryos. These results demonstrate that calcium independently affects two different aspects of the embryo development, i.e. DNA synthesis and cell division. It is suggested that the former effect is calmodulin-dependent, while the latter involves the calcium-dependence of metabolite transport through the cell membranes.     

Qualitative patterns of protein synthesis in the preimplantation mouse embryo: I. Normal pregnancy

Qualitative patterns of protein synthesis in preimplantation mouse embryos were examined by SDS-polyacrylamide-gel electrophoresis followed by autoradiography. The results demonstrate that the qualitative pattern of protein synthesis in newly fertilized eggs (day 1) is very similar to the protein pattern obtained from ovulated, unfertilized eggs. By late day 1 or early day 2, most of these “maternal” proteins are no longer being synthesized by the embryo, and many new autoradiographic bands are apparent. The most intriguing aspect of this study is the observation that all major changes in the qualitative pattern of protein synthesis take place between fertilization and the four- to eight-cell stage (day 3). From early day 3 onward, the qualitative pattern of protein synthesis remains essentially unchanged.Many of the major autoradiographic bands observed in mouse embryos from the four- to eight-cell stage and onward are also observed in protein patterns obtained from blastocyst-stage rabbit embryos. The changing patterns of protein synthesis revealed in this study occur before any gross differentiation of the embryos is evident (delineation of the inner cell mass and trophoblast) and before a marked increase in the relative rate of incorporation of l-[³⁵S]methionine takes place. However, the qualitative changes in the pattern of protein synthesis do coincide with a period of extensive fine structural differentiation.     

Changing rates of DNA and RNA synthesis in Drosophila embryos

Rates of DNA and RNA synthesis during Drosophila embryogenesis were measured by labeling octane-treated embryos with [¹⁴C]thymidine and [³H]uridine. Radioactivity incorporated per hour was converted to rates of synthesis using measurements of the pool-specific activity during the labeling periods. The rate of DNA synthesis during early embryogenesis increases to a maximum at 6 hr after oviposition and then decreases sharply. Measured rates of DNA synthesis were used to calculate that the total amount of DNA per embryo doubles every 18 min at blastoderm, every 70–80 min during gastrulation, and less than once every 7 hr at later stages. The rate of RNA accumulation per embryo increases continuously during the first 14 hr of embryogenesis. The rate of nuclear RNA synthesis per diploid amount of DNA, however, decreases fivefold between blastoderm and primary organogenesis. The cytoplasmic poly(A)⁺ RNA synthesized by blastoderm embryos associates rapidly with polysomes. The relatively high rate of synthesis of polysomal poly(A)⁺ RNA per nucleus at blastoderm allows the small number of nuclei present at blastoderm to make a significant quantitative contribution to the informational RNA active in the early embryo. At the end of blastoderm, approximately 14% of the mRNA being translated in the embryo has been synthesized after fertilization.     

Dual blastomere analysis improves reliability of preimplantation trembler mouse diagnosis

Dual blastomere biopsy and independent blastomere analysis dramatically improved preimplantation diagnostic reliability as confirmed by testing the remaining biopsied eight-cell mouse embryo. The autosomal dominant trembler mouse point mutation was selected as a model for human preimplantation diagnosis because: (1) single cell assay failure is predicted to be the highest when testing autosomal dominant mutations; (2) point mutations represent the most common of all mutation categories and the most demanding mutation to assay reliably; and (3) the trembler mouse point mutation in peripheral myelin protein 22 (Pmp22) is a model of human Charcot-Marie-Tooth type 1A disease. Mathematical models predict our experimental results assuming amplification of 80% of each target allele as well as trembler sperm DNA contamination in 1 of 44 normal biopsied single blastomeres. Single blastomere analysis correctly predicted the genotype in only 84% of embryos that would have been implanted as normal. In contrast, when independent tests of both biopsied blastomeres agreed, test results were confirmed in 20 of 21 (95.2%) of the remaining six-cell biopsied embryos designated as normal. Thus, biopsied six-cell embryo confirmation demonstrated that dual biopsied blastomere analysis improved test reliability remarkably. Received: 20 November 1996 / Accepted: 4 April 1997     

The effects of aphidicolin and α-amanitin on DNA synthesis in preimplantation mouse embryos

The effects of aphidicolin and α-amanitin on DNA synthesis by preimplantation mouse embryos were studied. It was found that both blastocyst and 8-cell embryos showed marked inhibition of ³H-thymidine incorporation into DNA by aphidicolin at concentrations of 20–50 μg/ml. However, aphidicolin did not inhibit the conversion of morula embryos to blastocyst embryos, although aphidicolin-treated blastocysts lost their blastocoel and collapsed into a compact form after prolonged exposure to the drug. Both 8-cell and blastocyst embryos were found to be susceptible to inhibition of DNA synthesis by α-amanitin.     

Effects of cordycepin on macromolecular synthesis and development in the preimplantation mouse embryo

Investigations were conducted to test the effects of cordycepin, a naturally-occurring analog of adenosine, on gene activity in preimplantation mouse embryos. Embryos were explanted into culture at the 2-cell, morula and blastocyst stages, and incubated in the absence or presence of cordycepin (5–100 μg/ml) to determine the effects of the drug on continued development and macromolecular synthesis. Cordycepin at concentrations exceeding 10 μg/ml caused a dose-responsive inhibition of cleavage and blastulation of embryos in culture. Exposure of morulae and blastocysts to cordycepin concentrations of 10–100 μg/ml produced a dose- and time-dependent suppression of RNA synthesis as measured by incorporation of [³H]uridine. Suppression in blastocyst-stage embryos was enhanced by preincubation, and reached 70% after 4 h at 100 μg/ml. Cordycepin (50–100 μg/ml) reduced synthesis of major RNA components detected by electrophoresis, blocked incorporation of radioactivity into fractions bound by olido(dT)-cellulose, and produced a time- and dose-dependent reduction of protein synthesis in blastocysts, causing a maximum inhibition of 25% after 4 h of preincubation at 50 μg/ml.     

Protein kinase Akt2/PKBβ is involved in blastomere proliferation of preimplantation mouse embryos

Activation of Akt/Protein Kinase B (PKB) by phosphatidylinositol-3-kinase (PI3K) controls several cellular functions largely studied in mammalian cells, including preimplantation embryos. We previously showed that early mouse embryos inherit active Akt from oocytes and that the intracellular localization of this enzyme at the two-cell stage depends on the T-cell leukemia/lymphoma 1 oncogenic protein, Tcl1. We have now investigated whether Akt isoforms, namely Akt1, Akt2 and Akt3, exert a specific role in blastomere proliferation during preimplantation embryo development. We show that, in contrast to other Akt family members, Akt2 enters male and female pronuclei of mouse preimplantation embryos at the late one-cell stage and thereafter maintains a nuclear localization during later embryo cleavage stages. Depleting one-cell embryos of single Akt family members by microinjecting Akt isoform-specific antibodies into wild-type zygotes, we observed that: (a) Akt2 is necessary for normal embryo progression through cleavage stages; and (b) the specific nuclear targeting of Akt2 in two-cell embryos depends on Tcl1. Our results indicate that preimplantation mouse embryos have a peculiar regulation of blastomere proliferation based on the activity of the Akt/PKB family member Akt2, which is mediated by the oncogenic protein Tcl1. Both Akt2 and Tcl1 are essential for early blastomere proliferation and embryo development.     

Glucose 6-phosphate dehydrogenase activity in the early rabbit and mouse embryo

Glucose 6-phosphate dehydrogenase (G6PD) activity was measured in individual preimplantation rabbit and mouse embryos. Substrate turnover by the enzyme is at least 30 times greater than glucose oxidation by the pentose shunt in the early rabbit embryo. There was no evidence during the preimplantation period of the embryos in either species of a bimodal distribution of G6PD activities among the embryos. Since cytological studies have not shown that inactivation of the X chromosome occurs during the early cleavage period and G6PD activity is sex-linked and gene-dose dependent in most higher animals, the evidence from the enzyme studies suggests that there is little or no synthesis of G6PD during the early preimplantation period. It is suggested that the enzyme is synthesized during oocyte development and the high levels of the enzyme found during the preimplantation period reflect the requirement of an earlier stage in oocyte development rather than the requirements of cleavage.Financial support for this work was obtained from National Institutes of Health Grants HD 03071 and HD 02315.     

Cloning and sequencing of buffalo male-specific repetitive DNA: sexing of in-vitro developed buffalo embryos using multiplex and nested polymerase chain reaction

Buffalo Y-chromosome specific repetitive DNA (BuRY.I) was cloned and sequenced in order to develop a sensitive method for sexing of buffalo preimplantation stage embryos using polymerase chain reaction (PCR). A highly sensitive and reliable sex determination assay using a primary (BRY.I), nested (BuRYN.I) and multiplex (BuRYN.I, ZFX/ZFY) PCR was developed. The BRY.I and BuRYN.I primers are targeted to amplify Y-specific sequences, while the ZFX/ZFY loci was amplified to serve as a positive control for both male and female samples. Accuracy of the sex determination assay was initially verified with genomic DNA obtained from blood of known gender. Further sensitivity and reproducibility of the assay was examined using DNA obtained from 1 or 2 blastomeres to demi embryos. Altogether, 80 IVF-derived embryos ranging from the 2 to 4 cell to the blastocyst stage were used for sex determination. Definite and clear signals following PCR amplification were obtained from all embryo samples. Accuracy of assays was determined by comparing results from a single cell with those of blastocyst stage embryos, thereby indicating that 1 or 2 blastomeres from a preimplantation buffalo embryo is sufficient for sex determination by PCR. No misidentification was observed within the embryo samples using nested (BuRY.I), primary (BRY.I) and multiplex (BuRYN.I; ZFX/ZFY) PCR, suggesting that this technique is a highly reliable method for sexing buffalo embryos.     

Serotonin localization and its functional significance during mouse preimplantation embryo development

Serotonin is a neurotransmitter functioning also as a hormone and growth factor. To further investigate the biological role of serotonin during embryo development, we analysed serotonin localization as well as the expression of specific serotonin 5-HT1D receptor mRNA in mouse oocytes and preimplantation embryos. The functional significance of serotonin during the preimplantation period was examined by studying the effects of serotonin on mouse embryo development. Embryo exposure to serotonin (1 microM) highly significantly reduced the mean cell number, whereas lower concentrations of serotonin (0.1 microM and 0.01 microM) had no significant effects on embryo cell numbers. In all serotonin-treated groups a significant increase in the number of embryos with apoptotic and secondary necrotic nuclei was observed. Expression of serotonin 5-HT1D receptor mRNA in mouse oocytes and preimplantation embryos was confirmed by in situ hybridization showing a clearly distinct punctate signal. Immunocytochemistry results revealed the localization of serotonin in oocytes and embryos to the blastocyst stage as diffuse punctate cytoplasmic labelling. It appears that endogenous and/or exogenous serotonin in preimplantation embryos could be involved in complex autocrine/paracrine regulations of embryo development and embryo-maternal interactions.     

Intracellular pH regulation in the early embryo

Intracellular pH (pHi) regulation is a homeostatic function of all cells. Additionally, the plasma membrane-based transporters controlling pHi are involved in growth factor activation, cell proliferation and salt transport – all processes active in early embryos. pHi regulation in the early embryos of many species exhibits unique features: in mouse preimplantation embryos, mechanisms for correcting excess acid apparently are inactive, while excess base is removed by the mechanism common in differentiated cells. Additionally, unlike differentiated cells, mouse preimplantation embryos are highly permeable to H⁺ until the blastocyst stage, where the epithelial cells surrounding the embryo are impermeable. In several non-mammalian species, of which the best-studied is sea urchin, cytoplasmic alkalinization at fertilization is necessary for development of the embryo, and elevated pHi must be maintained during early development. Thus, pHi regulatory mechanisms appear to be important for early embryo development in many species.