Activity of Embryonic Mink Genome during Diapause (Cytogenetic Analysis): Nucleolar and Extranucleolar RNA Synthesis

The nucleolar and extranucleolar RNA synthesis was studied in the mink blastocysts at different stages of embryonic diapause and during the periimplantation period using cytoradioautography. The data obtained suggest a differential and stage specific activity of the embryonic mRNA and rRNA synthesis during the period of delayed implantation.     

Luteal cell steroidogenesis in relation to delayed embryonic development in the Indian short-nosed fruit bat,Cynopterus sphinx

The primary aim of this study was to determine the possible cause of slow or delayed embryonic development in Cynopterus sphinx by investigating morphological and steroidogenic changes in the corpus luteum (CL) and circulating hormone concentrations during two pregnancies of a year. This species showed delayed post-implantational embryonic development during gastrulation of the first pregnancy. Morphological features of the CL showed normal luteinization during both pregnancies. The CL did not change significantly in luteal cell size during the delay period of the first pregnancy as compared with the second pregnancy. The circulating progesterone and 17β-estradiol concentrations were significantly lower during the period of delayed embryonic development as compared with the same stage of embryonic development during the second pregnancy. We also showed a marked decline in the activity of 3β-hydroxysteroid dehydrogenase, P450 side chain cleavage enzyme, and steroidogenic acute regulatory peptide in the CL during the delay period. This may cause low circulating progesterone and estradiol synthesis and consequently delay embryonic development. What causes the decrease in steroidogenic factors in the CL during the period of delayed development in C. sphinx is under investigation.     

Utilization of ketone bodies by chick brain and spinal cord during embryonic and postnatal development

Lipid synthesis from acetoacetate and 3-hydroxybutyrate was studied in chick embryo from 15 to 21 days and in chick neonate from 1 to 21 days. Embryonic spinal cord showed higher ability than brain to incorporate acetoacetate into total lipids, although a sharp decrease was found at hatching. 3-Hydroxybutyrate incorporation into total lipids was also higher in spinal cord than in brain, especially during the embryonic period. Phospholipids were the main lipids formed in both tissues from both precursors. An appreciable percentage of radioactivity was also recovered as free cholesterol, especially during the embryonic phase. The developmental patterns of amino acid synthesis from acetoacetate and 3-hydroxybutyrate were similar in both tissues: a clear increase after hatching was followed by a decrease at day 4 of neonatal life. Acetoacetate was a better substrate for amino acid synthesis than 3-hydroxybutyrate during the embryonic development in both tissues. Oxidation of both precursors to CO₂ strongly decreased between 15 and 21 days of embryonic development both in brain and spinal cord.     

DNA Replication in Permeabilized Cells of Sea Urchin Embryos

For study of the regulation of DNA replication in sea urchin embryos during the early stages of development, an embryonic cell system that was permeable to exogenously supplied nucleotides was established. Embryos were permeabilized by incubating them in hypotonic buffer containing 0.3 M glucose. The permeabilized embryonic cells maintained their morphological integrity, and synthesized DNA when supplied with exogenous dNTPs.
DNA synthesis in these permeabilized embryonic cells required the presence of ATP and three other deoxyribonucleoside triphosphates in addition to labeled dTTP. DNA synthesis was almost completely inhibited by N-ethylmaleimide, and proceeded in a discontinuous fashion. Only cells permeabilized during the S phase could incorporate nucleoside triphosphates into DNA: cells permeabilized during other phases did not synthesize DNA. During a 60 min-incubation period, over 10% of the genomic DNA was replicated under the experimental conditions used.     

Studies on Greening of Etiolated Seedlings

Evidence is given that a selective light-pretreatment of the embryonic axis exerts a deep influence on the greening in primary leaves of 8-day-old etiolated bean seedlings (Phaseolus vulgaris cv. Limburg). After a subsequent dark incubation of sufficient length and a final exposure of the entire plants to continuous illumination the lag phase of chlorophyll synthesis is completely removed. In particular the highly meristematic hook tissue seems to be responsible for this light effect. Lengthening of the dark period following pre-irradiation increased the capability of chlorophyll production in the main white light period, reaching its maximum after about 12 hours of darkness. The period of dark incubation for elimination of the lag phase is considerably longer in plants with shielded leaves than the length of the lag phase in etiolated seedlings of the same age, exposed entirely to continuous light. This difference may be explained by the synergistic effect between leaves and embryonic axis. Evidence for this interorgan cooperation is given by experiments with a selective light-pretreatment of leaves and embryonic axis. After a 5 min pre-exposure to white light of whole plants the leaves of some of the plants were shielded and these plants received a further pre-illumination of 2 hours on their embryonic axis. In all the pre-irradiated, etiolated plants the lag phase of chlorophyll synthesis was eliminated during the main white light period, following a dark incubation of 2 hours. Additional and preferential light activation of the embryonic axis during the pretreatment had no significant effect on chlorophyll production during the white light illumination after a 2 hours dark incubation, but resulted in a lower yield of chlorophylls after 18 hours dark incubation compared to the white light controls, receiving no selective light-pretreatment on the embryonic axis. From our results we can decisively conclude that a simultaneous light-pretreatment of both, leaves and embryonic axis, is more effective and beneficial for building up a capacity of chlorophyll synthesis in the leaves than either a selective light-pretreatment of the embryonic axis alone or a simultaneous pre-illumination of leaves and embryonic axis, immediately followed by an additional preirradiation of the embryonic axis. Therefore, we think that several photoactive sites are involved in de-etiolation processes of intact, etiolated seedings. Light activation of the embryonic axis stimulates the development of this organ and contributes to the greening processes in the leaf. At the same time, by irradiating the leaf, light activates the photo-sensitive site in the leaf itself, which also develops a capacity for chlorophyll synthesis. Both photo-acts are cooperative, explaining the enhanced chlorophyll production. Additional pre-irradiation of the embryonic axis after a short illumination of whole plants favours its own development and reduces the synthetic capacity of the leaf. A prolonged far-red pretreatment induces qualitatively the same response as white light. We assume that these effects on lag phase removal and chlorophyll production, induced in etiolated, primary bean leaves by selective irradiation of the embryonic axis, is a phytochrome-mediated process. Our results indicate a transmission of light-induced stimuli from one organ to another.     

Synthesis, accumulation and turnover of carbamoylphosphate synthetase and phosphoenolpyruvate carboxykinase in cultures of embryonic rat hepatocytes

Glucocorticosteroid, thyroid hormones and cyclic AMP can induce the synthesis of carbamoylphosphate synthetase and phosphoenolpyruvate carboxykinase in cultures of hepatocytes as soon as these cells differentiate from the embryonic foregut. The low levels of both enzymes that can accumulate in such still protodifferentiated hepatocytes are due to low levels of enzyme synthesis. In cultures, the rate of synthesis of both enzymes increases continually in the presence of hormones, showing that maturation of the capacity for synthesis towards the postnatal, fully differentiated situation is occurring in these cells. The turnover rate of both enzymes in embryonic hepatocytes is lower in the presence of hormones than in the absence, but does not change during the culture period. In the presence of hormones the turnover rate is comparable to that found in adult rat liver in vivo. The development of the capacity to accumulate organ-specific enzymes in vitro (and hence the rate of enzyme synthesis) is found to be comparable to that in utero.     

Messenger RNA synthesis during early ascidian development.

RNA synthesis during early embryogenesis of the ascidian Ciona intestinalis was studied. Embryonic polyribosomes labeled with uridine from 5 to 7 hr after fertilization were isolated and the labeled RNA species were characterized by oligo(dT)-cellulose chromatography and sucrose gradient sedimentation analysis. Since at least 50% of the labeled RNA was polyadenylated and all of it sedimented heterogeneously, it was concluded that mRNA was synthesized during the labeling period. Further, the synthesis of heterogeneously sedimenting, polyadenylated RNA at various stages of development from midcleavage to metamorphosis indicated that gene activity and perhaps mRNA synthesis occurred at earlier and later stages of development as well. Autoradiographic studies showed that the embryonic genome was the site of this activity, since uridine incorporation was localized in embryonic cells and not in accessory cells. Finally, under the labeling conditions employed (2-hr pulses), rRNA synthesis was not detected until larvae hatched.     

Synthesis of type I and type II collagen by embryonic chick cartilage

Embryonic chick articular and keel cartilage was found to synthesize two types of collagen. The amount of Type I collagen synthesis decreased from 60% to nearly 10% during the embryonic period studied, thus suggesting not only coexistence of both collagen types in the same tissue, but also a developmental transformation from predominantly Type I synthesis to Type II synthesis with cartilage development and maturation. Radioautographs suggested that all chondrocytes were equally active in collagen synthesis and failed to show any significant non-cartilagenous tissue contamination. Therefore variation in collagen type synthesis must be a product of some unknown genetic regulatory mechanism within the cartilage tissue.     

Rates of ribosomal protein and total protein synthesis during Drosophila early embryogenesis

Embryos at various stages of early development from 1.5 to 5 hr after oviposition were made permeable with octane and labeled for 1 hr with [³H]phenylalanine. Measurements of the rate of incorporation of [³H]phenylalanine into ribosomal proteins and total protein were made using these synchronized Drosophila embryos. The rate of synthesis of those ribosomal proteins incorporated into ribosomes increases until 3 to 4 hr after fertilization (550 pg/embryo-hr) then declines later in embryonic development. The rate of total protein synthesis is maximal as early during embryonic development as could be measured. During the period between 1.5 and 2.5 hr after fertilization this rate is 9.4 ng/embryo-hr and then also declines. The synthesis of ribosomal proteins accounts for a substantial portion (4.5%–8.9%) of total protein synthesis in early embryos. These results indicate that ribosome formation is a significant activity during the earliest stages of Drosophila development.     

Embryonic development of 2 strains of mice in the early cleavage period

RNA metabolism at 1-, 2- and 8-celled stages was studied in C3H and C57Bl mice by means of detection of RNA content in individual embryos and microcolumnal chromatography of lysate of the embryos labelled with 3H-uridine. The increase of RNA content in the 8-celled embryos of the both strains is due to active synthesis of high and low molecular weight RNAs during this period. A comparison of 3H-uridine incorporation in RNA, and nucleotide fractions of 2-celled embryos has shown that the embryonic genome per se is activated earlier in C3H mice. The embryonic development and RNA changes in them are similar in the pure bred and hybrid embryos with common mothers. This serves as an additional evidence of the leading role of maternal factors in embryonic development during the first cleavage divisions.     

Selective effects of actinomycin D on myosin biosynthesis and myoblast fusion during myogenesis in culture

The regulation of myosin biosynthesis in primary culture from embryonic chick muscle has been studied by measuring the residual myosin synthesis and the rate of fusion after actinomycin treatment. It is shown that while the rate of fusion is completely unaffected by an 8-h treatment with the inhibitor, throughout culture, the myosin biosynthesis shows different levels of inhibition during culture. In fact at onset of fusion (53 h) myosin synthesis is strongly inhibited, while at a later period following fusion (100 h) it is scarcely affected by the treatment.     

Hyaluronate production and removal during corneal development in the chick

Glycosaminoglycan (acid mucopolysaccharide) synthesis was studied during development of the embryonic chick cornea by the introduction of isotopically labeled precursors both in ovo and to excised corneas in culture. Results obtained for both types of preparations were similar. Hyaluronate is the major glycosaminoglycan synthesized by the embryonic cornea between stages 24 and 35, a period during which the primary corneal stroma swells and is invaded by mesenchymal cells. Subsequent to the completion of invasion a rapid decline in incorporation of isotopic precursors into hyaluronate occurs concomitant with an increasing hyaluronidase activity. The hyaluronidase is present primarily between stages 35 and 38, when the cornea begins to dehydrate prior to becoming transparent.     

Role of putrescine in ovary and embryo development in fruit bat Cynopterus sphinx during embryonic diapause

The aim of this study was to evaluate the effect of putrescine on ovarian activity and the rate of embryonic development in Cynopterus sphinx during delayed development. The result showed the presence of a rate‐limiting enzyme, ornithine decarboxylase‐1, in both ovary and utero‐embryonic unit of C. sphinx suggests a synthesis of putrescine in these sites. The corpus luteum showed increased, whereas utero‐embryonic unit showed decreased production of putrescine during delayed development as compared with the normal development. The bat treated in vivo with putrescine during delayed development showed increase in progesterone and estradiol synthesis, correlated with increased expression of luteinizing hormone receptor, steroidogenic acute receptor protein, and 3β‐hydroxysteroid dehydrogenase through extracellular signal‐regulated kinase (ERK1/2)‐mediated pathway in the ovary; but showed increase in the weight and expression of progesterone receptor (PR), B‐cell lymphoma 2, proliferating cell nucleus antigen, and vascular endothelial growth factor proteins in utero‐embryonic unit. The in vitro treatment of putrescine showed stimulatory whereas treatment with an inhibitor of putrescine, 2‐difluoromethylornithine caused an inhibitory effect on ovarian progesterone synthesis and cell proliferation, and cell survival in the utero‐embryonic unit. In conclusion, the putrescine showed two separate roles during embryonic diapause, high concentration of putrescine in the ovary may support corpus luteum and basal synthesis of progesterone, whereas a low level of putrescine causes retarded embryonic development by inhibiting cell proliferation in the utero‐embryonic unit. The bat treated with putrescine either directly promotes cell proliferation, cell survival, and angiogenic activities or acts indirectly increasing PR on utero‐embryonic unit thereby activating development in delayed embryo in C. sphinx.     

Interconversion and translocation of free sugars during galactomannan utilization in germinating guar (Cyamopsis tetragonoloba) seed

With the onset of the degradation of galactomannan, the galactose and mannose levels increased in the endosperm. The hydrolysis of galactomannan was more or less complete within the first 3 days of germination. In the cotyledons, sucrose was the predominant free sugar during the period of rapid galactomannan hydrolysis and reducing sugars (glucose + fructose) were present in only 10–20% proportion. The level of soluble acid invertase activity was in the order of embryonic axis > endosperm > cotyledons. On the basis of (a) absence of galactose and mannose, (b) high proportion of sucrose, (c) very fast conversion of [¹⁴C]glucose and [¹⁴C]mannose to [¹⁴C]sucrose and (d) very low levels of both soluble and bound invertases in cotyledons, we conclude that there is an active synthesis of sucrose in this tissue where disaccharide seems to be least hydrolysed during the period of galactomannan mobilization. A rapid hydrolysis of galactomannan in endosperm during early germination resulted in the synthesis of some starch, as a temporary reserve, in cotyledons. When the cotyledons entered the phase of first leaf formation, cotyledonary sucrose was hydrolysed giving rise to invert sugars. In the embryonic axis, the increase in the ratio of reducing sugars to sucrose coupled with a higher level of invertase, compared with sucrose-UDP glucosyl transferase, indicated that free sugars from the cotyledons are translocated to the embryonic axis as sucrose.     

Cell-type-specific expression of transforming growth factor-alpha in the mouse uterus during the peri-implantation period.

Immunohistochemistry as well as in situ and Northern blot hybridization were employed to determine temporal and cell-type-specific expression of transforming growth factor-alpha (TGF-alpha) in the mouse uterus during the peri-implantation period. The co-localization of TGF-alpha (by immunohistochemistry) with its mRNA (by in situ hybridization) in the luminal and glandular epithelia on Days 1-4 of pregnancy (Day 1 = vaginal plug) and also in many stromal cells on Days 3 and 4 indicates that these cells are the primary sites of TGF-alpha synthesis during the preimplantation period. The higher levels of TGF-alpha mRNA in total uterine RNA on Day 4, as shown by Northern blotting, is consistent with the recruitment of stromal cells expressing this gene. During the post-implantation period (Days 5-8), the co-localization of the mRNA and protein in the decidua at the implantation sites suggests that the decidualizing stromal cells synthesize TGF-alpha. Although in situ hybridization showed the presence of mRNA in embryos on Days 5-8, immunostaining was noted in the embryo only on Days 5 and 6. These results suggest that uterine and embryonic expression of TGF-alpha during the peri-implantation period could be involved in embryonic development, preparation of the uterus for implantation, and decidualization.     

Mitomycin C induced leaf mosaicism in Glycine max (L.) Merrill in relation to the post-germination age of the seed

Summary The frequency of mitomycin C induced somatic crossing over in variety L65-1237 of Glycine max is shown to be dependent upon the (physiological) age of the seed during post germination period. Effect of mitomycin C during the first four hr of germination is significantly lower than during later periods. This increase in the frequency of somatic crossing over is observed up to about 20–24 hr and is then followed by a decrease. These changes did not appear to be related to the onset and pattern of synthesis of DNA or/and proteins in the embryonic tissues. However, mitomycin C is effective even when no DNA synthesis is going on.     

Proteoglycan synthesis in the endothelium of embryonal vertebrate hearts: significance for the development of cardiovascular function

The endothelium of the embryonic heart is able to synthetize proteoglycans (PG) as it is the myocardium. In the extracellular matrix, PG form highly polymeric visco-elastic networks, which besides others act as shock absorber. That is apparently of evidence for the modulation of embryonic heart actions. Because during the embryonic period the large arteries are simple endothelial tubes without having an elastic-muscular wall. That means the typical "windkessel" function such as dumping of pulse waves or a continues pressure distribution is not existent. The embryonic vessels are perfused like rigid tubes. The continuous rhythmic flow pattern in the endothelial tubes, necessary for perfusion of the different organs, is apparently compensated by a high initial pressure level initiated by the heart. It is concluded that the continuity of the pressure profile is caused by intracardial PG. The endothelial synthesis of the PG of the heart decreases with increasing development of the muscular wall of the vessels and disappears completely post partum.     

Studies on the synthesis and degradation of DNA in developing and old chick cerebellum

The levels of DNA, RNA, protein and acid and alkaline DNase were studied in developing and old chick cerebellum. The in vitro synthesis of DNA, by both chick cerebrum and cerebellum was also studied, by following the incorporation of [3H]thymidine into DNA. It was observed that the increase in DNA content of chick cerebellum continued well beyond adult stages of life span. Maximal DNA synthesis, as judged by the [3H]thymidine incorporation, was noticed during the early embryonic development but decreased with advancement of age. There was, however, another peak of activity, although smaller, at about 9 months of age. Both cerebrum and cerebellum showed similar patterns. The highest specific activity of acid DNase was also found during the early period of cerebellar development, that is at a time when rapid cellular proliferation was occurring. The activity steadily declined with the aging and in 2-year-old cerebellum very little activity could be detected. Alkaline DNase, on the other hand, not only exhibited high activity during the early development but also remained at a significant level even in old cerebellum. It is concluded that acid DNase shows a positive correlation to the early embryonic DNA synthesis but not to the cell increase occurring in old age.     

The effect of maternal diabetes on glycogen metabolism in the embryonic rat

This study examined the effect of maternal hyperglycemia during pregnancy due to streptozotocin-induced diabetes on the synthesis of glycogen in the brain and liver of embryonic and newborn rats. Maternal hyperglycemia (serum glucose 25.3 +/- 0.9 mM) during gestation had no effect compared to controls (5.7 +/- 0.2 mM) on embryonic and newborn glycogen content in liver. In contrast, embryos experiencing hyperglycemia in utero had a two-fold higher brain glycogen content than controls at term; 1.6 mg/g vs. 0.84 mg/g, respectively. Interestingly there was a significant delay in the mobilization of brain glycogen during the immediate postnatal period in the offspring of diabetic mothers and control animals. These results suggest that uncontrolled maternal diabetes during pregnancy may significantly increase the availability of a potentially important local fuel source for the newborn brain: glycogen.     

Biosynthesis and metabolism of sulfated glycosaminoglycans during Drosophila melanogaster development

We developed a simple methodology for labeling sulfated glycosaminoglycans (GAGs) in adult Drosophila melanogaster and studied some aspects of the biosynthesis and metabolism of these polymers during development. Adult D. melanogaster flies were fed with Na(2)(35)SO(4) for 72 h. During this period, (35)S-sulfate was incorporated into males and females and used to synthesize (35)S-sulfate-heparan sulfate (HS) and (35)S-sulfate-chondroitin sulfate (CS). The incorporation of (35)S-sulfate into HS was higher when compared to CS. In a pulse-chase experiment, we observed that (35)S-sulfate incorporated into adult female was recovered in embryos and used for the synthesis of new (35)S-sulfate-GAGs after 2 h of embryonic development. The synthesis of CS was higher than that of HS, indicating a change in the metabolism of these glycans from adult to embryonic and larval stages. Analysis of the CS in embryonic and larval tissues revealed the occurrence of nonsulfated and 4-sulfated disaccharide units in embryos, L1 and L2. In L3, in addition to these disaccharides, we also detected significant amount of 6-sulfated units that are reported here for the first time. Immunohistochemical analysis indicated that HS and CS were present in nonequivalent structures in adult and larval stages of the fly. Overall, these results indicate that (35)S-sulfate-precursors are transferred from adult to embryonic and larval tissues and used to assemble different morphological structures during development.