Effect of 2,4-diamino-5-chlorphenyl-6-ethylpyrimidine on the oncorporation of P32-phosphate into adenylic nucleotides of rat embryo and placenta]

Teratogenic doses of antimalaria preparation, 2,4-diamino-5-p-chlorophenyl-6-ethylpyrimidine (chloridine), known in biochemistry as a specific inhibitor of dihydrofolate reductase, result in the decrease of 32P-phosphate incorporation into ATP and ADP, coupled with the inhibitions of DNA synthesis, in rat embryo and placenta on 13th day of development, while the incorporation of 14C-formiate into free nucleotides of acid soluble embryo and placenta fractions (at the same intervals after teratogen injections), is the same as in the control. These data show that the primary blocking of folate cycle and DNA biosynthesis in 13 days old embryos with induced anomalies of development is some way coupled with disturbances of ATP metabolism.     

Changes in phospholipid metabolism of SV3T3 transformed fibroblasts restricted by plating and cultivation at low serum concentration and subsequently re-stimulated by serum

We have studied 32P-phosphate incorporation, using 1 hour pulses, into phospholipids of SV3T3 transformed fibroblasts plated and cultured in a 1% serum medium. Two successive periods were observed:On the first 2 days after plating, cells grow exponentially with a lowered rate of multiplication. The percentages of incorporation of 32P-phosphate into the different phospholipids are then unchanged, but the rate of incorporation is decreased.On the 4th day, cells are almost completely arrested, and the percentages of incorporation into the different phospholipids are then sharply altered.If, during the first period, cells are subsequently re-stimulated by a medium containing 10% serum, i.e. by simply increasing the rate of exponential growth, it can be observed a response of phospholipid metabolism (for instance the “PI response”) similar to that which was previously reported as characteristic of untransformed fibroblasts.     

Effect of testosterone on the rate of total protein synthesis in the reproductive tract of rabbit embryos in vitro

The total protein synthesis rate in the reproductive tract and muscles of rabbit fetuses was evaluated at the 18th-22nd day of development by the intensity of 3H-leucine incorporation in experiments in vitro. Testosterone increased the total protein synthesis rate in the tissues of the reproductive tract at all the developmental stages under study. The highest rate of protein synthesis was recorded on the 18th day of development.     

Effect of DNA inhibitors upon DNA synthesis and development of Drosophila embryos

Staged wildtype embryos of Drosophila melanogaster were permeabilized and then subjected to a short pulse of either methyl-3H-thymidine, one of four different inhibitors of DNA synthesis (mitomycin C, 5-fluorouracil, nalidixic acid, or 1-beta-D-arabino-furanosylcytosine-5'-monophosphate), or a combination of both. The incorporation of methyl-3H-thymidine into acid insoluble material was at a maximum during the first half-hour of embryogenesis, after which the incorporation dropped to half the initial value and remained constant throughout the remainder of development. There was no correlation between the rate of incorporation of methyl-3H-thymidine into DNA and the known periods of high mitotic activity. The time course of the estimated specific activity of the DNA newly synthesized in vivo closely paralleled the known changes in the DNA polymerase activity determined in vitro. The known periods of high mitotic activity in the embryo (0-3 hours, 5-12 hours) agree with the periods of maximal sensitivity of the embryo to the inhibitors of DNA synthesis. All four DNA inhibitors affected the incorporation of methyl-3H-thymidine into DNA, although they did not affect it in any simplistic manner. Inhibitor treatment during early cleavage stages resulted in arrested development, treatment during late cleavage and blastoderm stages resulted in abnormal development, and treatment during late blastoderm and early gastrula resulted in normal development. The major phenotypic abnormality caused by the inhibitors is an abnormal distribution of blastoderm cells. As judged by the ID50 values, the embryos remained very sensitive to the effects of the inhibitors until the stages of head and body segmentation, when they then very rapidly became insensitive.     

Nature of Transient Inhibition of Deoxyribonucleic Acid Synthesis in HeLa Cells by Parainfluenza Virus 1 (Sendai)

Adsorption of ultraviolet-inactivated Sendai virus, at high or low multiplicity, to HeLa cells caused a transient increased incorporation of (3)H-thymidine into the cellular deoxyribonucleic acid (DNA). In HeLa cells synchronized by a double-thymidine block, this increased incorporation of thymidine during the S phase lasted from about 30 to 90 min after virus adsorption. The observations that the kinetics of accumulation of radioactive thymidine in the nucleotide pool did not differ in control and in the virus-treated cells and that the (32)P incorporation into the DNA of the virus-treated cells was inhibited at the same time indicate that the augmented incorporation of (3)H-thymidine into DNA results from a transient block in the endogenous pathway of thymidine synthesis. Chromatographic analysis of the nucleotide pool of the virus-treated cells labeled with (14)C-formate indicates that methylation of deoxyuridine monophosphate to thymidine monophosphate is inhibited. It is suggested that the inhibition is caused by a block of either the thymidilate synthetase or some step in the tetrahydrofolate cycle.     

The cholinergic reaction of the amnion in the chick embryo

Studies have been made of the spontaneous contractions of the amnion and acetylcholine sensitivity of amniotic membrane in 8--14-day chick embryos. In 12--14-day embryos, the spontaneous rhythmic contractions were rather rare as compared to those in 8--9-day ones, their frequency being also lower. On the basis of kinetic analysis, it was concluded that both the dissociation constant (K) and the value of Pmax do not exhibit significant changes for tonotropic reaction from the 8th to the 14th day and for chronotropic reaction--from the 8th to the 10th day of incubation. After the 10th day of incubation, dose-effect chronotropic reaction not expressed. The spontaneous activity of the amnion and acetylcholine sensitivity of the amniotic membrane depend on the temperature being maximal at 38 degrees C. Possible regulatory mechanisms of contractile activity in chick amnion are discussed.     

Activation, after medium replacement, of 32P-phosphate incorporation into phospholipids of succinyl-concanavalin A arrested fibroblasts.

When succinyl-concanavalin A arrested fibroblasts are incubated in culture medium lacking succinyl-concanavalin A, the cell cycle is triggered, and S phase occurs 12–14 hours later. In pulse experiments, 32P-phosphate incorporation into cell phospholipids is shown to fastly increase. When succinyl-concanavalin A arrested cells are incubated in succinyl-concanavalin A containing culture medium, the cells remain arrested, and yet an initial and transient activation of 32P-phosphate incorporation into phospholipids is observed.     

Effect of adrenocorticotropic hormone on nucleic acid and protein synthesis and content in the brain of rat embryos in the early stages of neurogenesis]

The injection of adrenocorticotropic hormone (ACTH) of prolonged effect at the doses of 4 and 10 M. U. to the intact rats from the 11th till the 15th day of pregnancy resulted in the twofold increase of protein content in the brain and its decrease in the liver of 15 days old embryos, as compared with the control ones. The content of DNA, RNA and proteins in the placenta of experimental animals increased as well. The rate of incorporation of 3H-thymidine in the liver DNA and 14C-leucine in the liver and brain acid-soluble protein decreased within small intervals of time following the treatment. The total radioactivity of proteins in the liver, brain and placenta calculated per DNA unit was similar to the control one whereas the specific radioactivity of total protein in the liver of experimental embryos was higher than in the control.     

Failure of tritiated thymidine incorporation into DNA to reflect the autoradiographically demonstrable calcium-induced increase in thymic lymphoblast DNA synthesis

Increasing the extracellular calcium concentration in thymic lymphocyte suspension from 0.6 to 1.8 mM stimulated the proliferation of the lymphoblast subpopulation as measured by increases in the proportion of cells autoradiographically labeled with ³H-TdR and in mitotic activity. However it was not possible to show this increased DNA synthesis by scintillometric measurement of the amount of ³H-TdR incorporated into extracted DNA. On the other hand, calcium did raise the incorporation of ¹⁴C-formate into the thymine residues of DNA, and increased the activity of isolated thymocyte thymidylate synthetase. In contrast to the mitogenic calcium ion, a thymidylate synthetase inhibitor, methotrexate, actually increased the incorporation of ³H-TdR into DNA. It is concluded that calcium increases the endogenous synthesis of thymidylate which in turn prevents the amount of incorporation of exogenous ³H-TdR from accurately reflecting the true level of DNA synthesis.     

TIMING OF INCORPORATION OF TRITIATED NUCLEOSIDES INTO DNA AND RNA OF EMBRYONIC CELLS OF RANA PIPIENS

The incorporation of tritiated nucleosides into DNA and RNA has been examined in partially synchronized cells of Rana pipiens embryos at the neurula and tailbud stages. Tritiated thymidine and deoxyguanosine are incorporated into the DNA in two maxima, or waves, during the S phase at both stages. More DNA replicates in the early maximum at the neurula stage than at the tailbud stage. A comparison of the degree of incorporation of labelled deoxyguanosine to labelled thymidine into DNA suggests that earlier replicating DNA at both stages may be GC-rich compared to later replicating DNA. The incorporation of tritiated uridine into RNA during the S phase also differs between the neurula and tailbud stages. Pulse and continuous label experiments indicate that at the neurula stage the highest rate of RNA synthesis occurs late in the S phase whereas at the tailbud stage the higher rate of RNA synthesis has shifted to an interval earlier in the S phase.     

Purine nucleotide catabolism in rat liver: labelling of uric acid and allantoin after administration of various labelled precursors

Uric acid and allantoin are the key compounds of purine nucleotide catabolism formed in liver and many other organs of the rat. We observed that, after administration of 14C-formate, incorporation of radioactivity into uric acid and allantoin is not similar, as one would expect. The phenomenon was demonstrated to be specific to liver and perfused liver, and not to other organs such as heart, jejunal mucosa, lung, spleen, and kidney. To interpret these results, the specific radioactivity of uric acid and allantoin in rat liver were analysed comparatively, after administration of the following labelled precursors: 14C-glycine, 14C-formate, 14C-hypoxanthine, 14C-uric acid and 14C-adenine. After administration of 14C-formate the specific radioactivity of allantoin was higher than that of uric acid and the same behavior was observed after 14C-uric acid and 14C-hypoxanthine, but not after 14C-glycine and 14C-adenine administration. The results indicate that the rate of their incorporation into uric acid and allantoin, and the subsequent export of these compounds into serum, can only partially explain the observed phenomenon, while the presence of different pools of uric acid and allantoin may give a complete explanation.     

Electrophoretic analysis of proteins synthesized by preimplantation mouse embryos

Proteins synthesized during the preimplantation period of mouse embryogenesis were labeled with radioactive tyrosine and lysine and fractionated by electrophoresis on polyacrylamide disc gels containing sodium dodecyl sulfate. For interstage comparisons and comparisons of the incorporation of different amino acids at the same developmental stages, the embryos were incubated with either ³H- or ¹⁴C-labeled amino acids. The embryos were then combined, and the proteins were isolated and electrophoresed simultaneously. The data were analyzed with a dual isotope computer program and expressed in the form of ¹⁴C/³H ratios.Approximately 20–25 labeled protein components of apparent molecular weights between 25,000 and 115,000 can be defined, and 5 are most significant quantitatively. Of the latter, there are developmental increases in the rates of synthesis of 3 (with apparent molecular weights of 35,000 to 37,000, 37,000 to 41,000, and 66,000 to 70,000), a decrease in the rate of synthesis of another (53,000 to 57,000), and little change in the last (46,000 to 49,000). Developmental changes in the rates of synthesis of several other components are also demonstrated by the ¹⁴C/³H incorporation ratios. The relative amounts of the different proteins synthesized by day 3 (early blastocyst) embryos over an 8-hr period remain constant, as does the relative labeling by lysine and tyrosine at each developmental stage examined. Similarly, there is no change in the pattern of the radioactive proteins when day 2 (8–16 cell) embryos are labeled for 2 hr and then incubated for an additional 24 hr. The greatest change in the overall pattern of protein synthesis occurs quite early, between day 1 (2 cell) and day 2, and lesser changes occur at later stages. These findings are in contrast to the major change in the rate of protein synthesis which occurs after day 2.     

Thymidine phosphorylase, thymidine kinase and thymidylate synthetase activities in cerebral hemispheres of developing chick embryos

The changes in activities of thymidine phosphorylase (EC 2.4.2.4), thymidine kinase (EC 2.7.1.75) and thymidylate synthetase (methylenetetrahydrofolate:dUrd-5′-P C-methyltransferase, EC 2.1.1.-) in the cerebral hemispheres of developing chick embryos were determined and compared with the course of DNA synthesis and of natural cell death in this organ. Thymidine phosphorylase activity reaches a broad maximum at the 12th to 14th day of incubation, followed by a rapid decrease. Thymidine kinase and thymidylate synthetase activities are highest at the earliest time studied (day 10) and decrease until day 14, followed by an increase from day 14 to 16 and a further decrease from day 16 through 1 day post-hatching. The rate of DNA synthesis essentially follows these activities, but the increase at day 16 is not discernible. Our previous study revealed high DNA synthesis at day 10, with natural cell death concurring on days 12-14, followed by another peak after day 16 (glial proliferation) and a decrease after day 16. It appears that thymidine phosphorylase activity reaches a maximum (days 12-14) at the time of maximum cell death, which may be correlated with the degradative function of this enzyme. This was also the time for minimum activities of thymidine kinase and thymidylate synthetase; on the other hand, these activities reach a first (day 10) and second (day 16) maximum at the time of maximum DNA synthesis; this may be correlated with the synthetic functions of these enzymes.     

Action of acetazolamide on the chick embryo during late development.

Acetazolamide was injected into chick embryos on the 14th or 15th day of incubation. Doses ranging between 5 and 10 mg per egg produced a retardation in the growth of long bones. The affected bones contained a normal proportion of mineral as determined by ashing and presented a normal histological picture. On the basis of these findings, it is suggested that the alterations were not due to a specific direct effect of the drug on bones. The incorporation of 131-I by the thyroid glands of acetazolamide-injected embryos was analyzed radioautographically and quantitated on the same 6 mu-paraffin sections, with a thin window Geiger counter. The incorporation appeared notably reduced 3 h after the injection of acetazolamide and the reduction persisted for a least 24 h.the electron microscopical observation of thyroid follicular cells from similarly treated embryos showed that the cytological characteristics indicating an active protein synthesis were unmodified with respect to those found in control embryos. These results may indicate that acetazolamide inhibits the iodination of the throid hormone without interfering with the synthesis of the globulin. It is suggested that the growth retardation observed in the embryos treated with acetazolamide may be secondary to the action of the drug on the thyroid gland, although this action appears to be a transitory one.     

Embryotoxic effects of doxorubicin and N-trifluoroacetyladriamycin-14-valerate (AD-32)

Anthracyclines are mutagenic, carcinogenic, and also cardiotoxic. Concern has been shown over the use of anthracycline anticancer drugs during pregnancy as these may be teratogenic to the human fetus. We have performed a series of experiments using the chick embryo to investigate and compare the toxic and teratogenic effects of doxorubicin (DX) and its new analog N-trifluoroacetyladriamycin-14-valerate (AD-32). DX and AD-32, dissolved in 1:1 emulphor/ethanol and diluted to 1:4 with water, were injected into the air sac of white leghorn chick eggs at dose levels of 1-20 micrograms (DX) and 5-100 micrograms (AD-32) per egg. Eggs received a single injection of the drugs on days 1 and 2 of incubation. Control eggs were injected with an equivalent volume of the drug vehicle (0.05 ml per egg). Both of the drugs caused embryonic death, stunted growth, and various gross morphological malformations. Surviving embryos were sacrificed when they reached 13 days of incubation. The LD50 values for days 1 and 2 were as follows: (DX, 2.5 micrograms/egg on day 1 and 0.9 microgram/egg on day 2; AD-32, 10.6 micrograms/egg on day 1 and 11.8 micrograms/egg on day 2). Stunting of growth, a common anomaly with both drugs, decreased sharply from day 1 to day 2. The studies demonstrate that both DX and AD-32 are toxic and teratogenic during the period of early organogenesis in the chick embryos. However, the toxic and teratogenic potentials of DX and AD-32 differ quantitatively. AD-32 is a more potent teratogen than DX when injected on day 1.     

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.     

Phosphate depletion decreases mitogen-mediated stimulation of phospholipid synthesis in human peripheral lymphocytes

Concanavalin A-mediated stimulation of ³²P-phosphate incorporation into phospholipids of human peripheral lymphocytes is comparatively studied in normal and phosphate-depleted media. In the phosphate-depleted medium, 2 hours after the start of cell activation, the stimulation sharply decreases for phosphatidylinositol (6.5-fold) and for phosphatidylcholine (in the latter case, the stimulation is even replaced by a slight inhibition of the incorporation). These results must be related to the rate-limiting effect of inorganic phosphate on ATP formation and thus on phospholipid synthesis, an effect which may be particularly pronounced when there is both phosphate depletion and cell activation.     

Pathways of purine nucleotide synthesis in the human trophoblast early and late in gestation

Purine nucleotide and nucleic acid synthesis were studied in cultures of human first and third trimester trophoblastic cells. De novo synthesis was measured as incorporation of 14C-formate into purine nucleotides. Reutilization of purine bases was evaluated by the incorporation of 14C-adenine and -hypoxanthine. Utilization of 14C-adenine was also studied. The incorporation of formate was significantly (P less than 0.01) less active in the third trimester cells. Adenine incorporation was an order of magnitude higher than that of formate in both first and third trimester cells, and significantly (P less than 0.001) higher in the first than third trimester cells. No change in the reutilization of hypoxanthine was observed as a function of gestational age, and the rate was not increased by high extracellular inorganic phosphate. Both phosphorylation and deamination of adenosine increased as a function of concentration up to at least 60 microM, and the high concentration was more efficiently utilized in the first trimester cells. The major pathways of purine nucleotide synthesis function in the human trophoblast throughout gestation, but the contribution of reutilization seems larger than that of de novo synthesis. First trimester trophoblast appears more active in nucleotide and nucleic acid synthesis. Hypoxanthine utilization appears not be enhanced by increased extracellular phosphate. Hypoxanthine may be the major precursor utilized in trophoblastic purine nucleotide synthesis.     

Comparative distribution and embryotoxicity of hydroxyurea in pregnant rats and rhesus monkeys.

Hydroxyurea was given to pregnant rhesus monkeys and pregnant rats in regimens adjusted to produce similar degrees of teratogenicity, for the purpose of comparing the distribution of the drug in the females and their embryos. According, in rats 137 mg/kg/day ip on days 9-12 resulted in a drug half-life in maternal plasma of about 15 min and in embryos about 85 min, after the last injection; and in monkeys 100 mg/kg/days iv on days 23-32 resulted in drug half-life in maternal plasma estimated to be 120 min and in embryos 265 min, after the last injection. Using as a baseline of biological effects the minimal concentration known to inhibit DNA synthesis in rat embryos and cancer cells, namely 10(-4) M, it was calculated that the rat embryos in the present study were exposed to this level or more for approximately 12 h whereas the monkey embryos were exposed for approximately 100 h. Although the teratogenic effects were not identical in the two species, these data are interpreted to mean that rat embryos are teratogenically much more sensitive to hydroxyurea than monkey embryos. These observations have important implications in the selection of appropriate species for tests to estimate human teratogenic risks. The rat, which is currently the most widely used animal for such tests, displays sizeable differences from rhesue monkeys, which is one of the animals thought to be most like man in teratogenic susceptibility.