Effects of metabolic substrates and ionic environment on in-vitro activation of delayed implanting mouse blastocysts

The possibility that the embryonic diapause associated with delayed implantation in mice is maintained by limitation of an essential amino acid, energy substrate or concentration of ions was examined by comparing the rates of DNA synthesis in delayed implanting embryos that were 'reactivated' by incubation in 'complete' medium or in one of several specially formulated 'deficient' media. It was found, in agreement with earlier observations, that an increase in the rate of DNA synthesis could be detected within 12 h and continued through 72 h in complete medium. An identical pattern was found when embryos were incubated in medium deficient in amino acids and vitamins. Similar patterns of activation were observed in the absence of all metabolizable substrates, a drastically reduced concentration of Na+, and even in a medium consisting only of 25 mM-bicarbonate buffer, NaCl and KCl. The embryos incubated in the more drastically deficient media appeared to be damaged after 18-24 h. Nevertheless, the observation that the rate of DNA synthesis did not remain depressed suggests that such deficiencies are not the means by which embryonic dormancy is maintained in utero.     

Size and specific activity of the UTP pool and overall rates of RNA synthesis in early mouse embryos

Mouse embryos from the one-cell to the blastocyst stage were cultured for 2 hr in the presence of 5 μM [³H]uridine or 10 μM [³H]adenosine, and the size and specific activity of the UTP and ATP pools were determined by an Escherichia coli RNA polymerase assay using synthetic poly(dA-dT) as template. The total UTP pool increased in size and specific activity with development from 0.05 pmole (0.06% labeled) in the one-cell stage to 0.54 pmole (27% labeled) in the blastocyst stage. The total ATP pool remained relatively constant in size at about 1 pmole/embryo, but increased in specific activity from 2.6 to 52% from one-cell to blastocyst. The turnover of the [³H]UTP pool was also examined under pulse-chase conditions in eight-cell and morula-stage embryos. The UTP pool decayed with approximately first-order kinetics up to 20 hr of chase, but the rate of decay was slower in eight-cell embryos (t_0.5 = 5.5 hr) than in morulae (t_0.5 = 2.8 hr). The observed specific activities of the UTP pools were used to calculate the overall rates of uridine incorporation into acid-precipitable material during early development. The rate of uridine incorporation per embryo increased from 3.6 × 10^?3 pmole/2 hr in the two-cell embryo to 1.8 × 10^?1 pmole/2 hr in the blastocyst. The rate of RNA synthesis per cell over a 2-hr period was estimated at 2.5 pg in the two- to four-cell embryo, 5 pg in the eight-cell, and 10 pg in the morula-early blastocyst.     

Actin mRNA content in normal and delayed implanting mouse embryos

Actin mRNA levels were measured in mouse eggs, early embryos, and delayed implanting blastocysts by a homologous, cloned recombinant DNA probe and "dot" blot methodology. A maternal store of 431 fg of actin mRNA was observed in the unfertilized eggs. This mRNA pool decreased 12-fold by the mid-two-cell stage. Actin mRNA levels were then observed to increase progressively from the eight-cell to the blastocyst stage on a basis proportional to cell number. Late blastocysts contained 2400 fg actin mRNA per embryo (22 fg per cell). The cellular level decreased by about 20% in embryos induced into delay of implantation by ovariectomy of donor females. Reactivation of the delayed implanting blastocysts through hormonal manipulation in vivo or culture in vitro was accompanied by reestablishment of the level of cellular actin mRNA observed in normal blastocysts.     

Chymotrypsin stimulated development of delayed implantation mouse blastocysts

Chymotrypsin-like enzyme activity increases transiently in the uterine lumen of ovariectomized mice upon administration of progesterone and estrogen (1). This is one of the few known macromolecular changes associated with conditions which result in activation of delayed implantation blastocysts $\text{in}$$\text{utero}$. $\text{In}$$\text{vitro}$, α-chymotrypsin (100 μg/ml) was found to shorten the time required for these embryos to attach to the glass culture dish and then form outgrowths in fetal calf serum-supplemented medium. Higher concentrations of the enzyme (250 μg/ml) prevented embryo attachment probably by digesting the fetuin present in fetal calf serum. Nevertheless, 250 μg/ml α-chymotrypsin could apparently replace fetal calf serum as a stimulator of development during the first 24 hours of culture. In contrast, bovine serum albumin (3.0 mg/ml) seemed to slow development of blastocysts $\text{in}$$\text{vitro}$. It is suggested that chymotrypsin-like enzyme activity may stimulate development of delayed implantation blastocysts $\text{in}$$\text{utero}$ (a) indirectly by removing inhibitory proteins such as albumin and (b) by directly affecting these embryos in a manner yet to be determined.     

Persistence of embryonic RNA synthesis during facultative delayed implantation in the mouse.

The status of embryonic RNA synthesis during facultative delayed implantation in the mouse has been examined by radiolabeling in vitro and in utero, and by assay for endogenous RNA polymerase activity. Under conditions that do not activate delayed blastocysts in utero, embryos were shown to be able to transport and incorporate [³H]uridine into RNA as early as 5 min after intralumenal instillation of label on Day 5 of delay. Assay for endogenous RNA polymerase demonstrated functioning enzyme(s) in blastocysts on Day 5 of delayed implantation. Rates of incorporation of label in vitro under nonactivating conditions indicated a reduction, from normal Day 5 blastocyst levels, of 52% on Day 2 and 36% on Day 5 of delay. Relative rates of uptake of [³H]uridine by blastocysts on Day 5 of delay were reduced by approximately 60% from rates observed in predelay embryos on Day 5 of pregnancy. Estrogen-induced activation of embryos in utero was not associated with an increased relative rate of ³H]uridine uptake or incorporation during the first 24 hr following activation on Day 5 of delay. The findings demonstrate that RNA synthesis persists in the mouse blastocyst during delayed implantation, although at a somewhat reduced level. Implications of these results relevant to the maternal regulation of embryonic growth and implantation are discussed.     

Factors influencing the in vitro hatching of mouse blastocysts

The influence of bovine serum albumin (BSA) concentration on embryo hatching and the number of embryos cultured per drop of culture medium was examined in F1 (C57BL/6J × DBA/2J), C3HeB/FeJ strain and Line E mice. Embryos collected from F1 and Line E mice exhibited uniform hatching rates at BSA concentrations between 1 and 10 mg/ml, and embryo numbers ranging from 1 to 10 per 3 μ1 of culture medium. The hatching of C3HeB/FeJ blastocysts was greater at the higher concentrations of BSA and higher embryo densities. When the C3HeB/FeJ embryos were grown at high densities until morula and then cultured singly in fresh media they hatched at a low rate. However, when allowed to develop until the blastocyst stage before replotting, the embryos hatched at a high rate. C3HeB/FeJ embryos cultured singly until morula and then placed in groups of 10 hatched at a high rate. Single C3HeB/FeJ embryos, cultured in medium conditioned by the prior presence of embryos at high densities, hatched at a slightly higher frequency than those cultured in fresh medium. There was no tendency of embryos developing from the two-cell to the eight-cell stages to hatch when cultured in the presence of high densities of hatching blastocysts.     

Inhibition of RNA synthesis in vitro by 9-aminoacridine carboxamide antitumor agents. Effects on overall RNA synthesis and synthesis of the initiating dinucleotide.

A series of 9-aminoacridine carboxamide derivatives of systematically varied structure was assayed in an RNA synthesis in vitro system. Escherichia coli DNA-dependent RNA polymerase and DNA derived from phage T7 or calf thymus were used to measure the effect of the drugs on overall RNA and the initiating dinucleotide (pppApU) syntheses. By means of multiple linear regression analysis it was shown that the inhibition of these reactions depends both on the drug equilibrium binding constant and kinetic parameters of dissociation of drug-DNA complexes.