Ultrastructure and 3H-thymidine incorporation by chromosome vesicles in sea urchin embryos

The ultrastructural features of chromosome vesicle formation in early sea urchin embryos and chromosome vesicle uptake of tritiated thymidine is described. Envelopes which resemble typical nuclear envelopes form around the condensed anaphase chromosomes. In late anaphase or early telophase, the chromosomes swell and decondense and it is at this time when tritiated thymidine is incorporated. This study shows that DNA synthesis in the rapidly dividing cells of early sea urchin embryos occurs in chromosome vesicles which form during anaphase.     

Erythropoiesis in the developing chick embryo

The types of erythroid cells of chick embryos developing in ovo have been correlated with the hemoglobins of the embryos. Prior to 5 days, when primitive cells constitute the only erythroid cells, two hemoglobins can be resolved by polyacrylamide gel electrophoresis. The two adult hemoglobins and a minor hemoglobin found only in embryos and young chicks first appear simultaneously with initiation of definitive erythropoiesis.     

SOME MORPHOLOGIC AND KINETIC STUDIES OF THE DEVELOPING ERYTHROID CELLS OF THE COMMON GOLDFISH, CARASSIUS AURATUS

Developing erythroid cells of the goldfish Carassius auratus were obtained from kidney prints and from smears of the peripheral blood. All preparations were stained with the May-Grunwald Giemsa technique. Developing cells were divided into six different stages. The criteria used to stage the cells were degree of chromatin condensation, degree of basophilia, nuclear:cytoplasmic ratio, and cell shape. The morphology of the maturation sequence for erythroid cells in this organism was similar to that found by other workers in other non-mammalian vertebrates. Fish received intraperitoneal injections of tritiated thymidine, tritiated uridine or tritiated leucine so that the stages involved in DNA synthesis, RNA synthesis and protein synthesis could be determined by means of autoradiography. For the tritiated thymidine studies the per cent labeled cells per stage from four different series receiving 0.5, 1.0, 3.0 or 6.0 μCi/g body weight were pooled, since subjecting the average per cent labeled cells per stage at the lowest and at the highest dosages to Student's t-test showed no significant differences. In all four series the fish were killed 2 hr, 12 hr and daily, 1–8 days post-injection. The ³H-TdR studies showed that stages I-IV were engaged in DNA synthesis; they also showed that about 5 days were required for the stage V cell to become a mature erythrocyte (stage VI cell). Tritiated uridine was injected at a dosage of 5.0 μCi/g body weight and animals were killed 1/2, 1, 3 and 6 hr post-injection. Grain counts showed that stages I-IV are engaged in RNA synthesis and that the rate of this synthesis decreased as maturation proceeded. Tritiated leucine was administered at a dosage of 5.0 μCi/g body weight, and fish were killed 45 min and 3 hr post-injection. Grain counts indicate that stages I-V are engaged in the synthesis of protein (assumed to be globin). The fact that DNA and RNA synthesis ceased with stage IV cells while protein synthesis continued into stage V cells indicated that the mechanism responsible for protein synthesis in stage V cells was produced at an earlier stage and was self-sustained for about 5 days.     

Immunohistochemical analysis of the distribution of histone H5 and hemoglobin during chicken development

We used immunohistochemical procedures to investigate embryonic erythropoiesis in serial sections of chicken embryos after 2-13 days of incubation. Antibodies specific for the erythrocyte-specific histone H5, for embryonic hemoglobin, and for adult hemoglobin were used as markers for general, primitive, and definitive erythropoiesis, respectively. Histone H5 was present in erythrocytes at all of the stages studied, i.e., in both the primitive and definitive cells. Cell of the definitive lineage were first detected, at about 5-6 days of incubation, in erythroid foci in the mesenchyme around the vitelline stalk. At 7-9 days of incubation, a massive mesenchymal conglomeration of erythropoietic cells developed, extending from the cervical to the abdominal region and ventrally to the vertebral body, with its largest extensions being around the arteries in the mediastinum. Immunostaining revealed that these erythroid cells belonged to the definitive erythropoietic lineage. These cells had disappeared completely after 12 days of incubation, i.e., before erythropoiesis is visible in the bone marrow. These observations are consistent with the notion that the yolk sac is essential for the formation of the definitive erythroid lineage.     

Evidences that hemoglobin switch in the chick embryo depends on erythroid cell line substitution

Chemical identifications of various hemoglobin types were performed on unfractionated erythroid cells derived from chicken embryos at 5 and 7 days of development and on purified primitive and definitive cells. Proteins were pulse-labelled in primitive erythroid cells at various times of culture to identify those actually synthesized. The data show that primitive cells contain and synthesize only embryonic hemoglobins at all stages of maturation and definitive cells contain adult and minor embryonic hemoglobins, but no major embryonic hemoglobins, not even in trace amounts. These results support a model for hemoglobin switch in the chicken embryo based on cell line substitution.     

Some Characteristics of DNA Synthesis and the Mitotic Cycle in Ehrlich Ascites Tumor Cells

In vivo studies of Ehrlich ascites tumor cells during the first 5 days of growth in peritoneal cavities of mice consisted of the following: 1. Determination of growth curves by direct enumeration of cells. 2. Estimation of the duration of each phase of the mitotic cycle based on incidence of cells in different phases. 3. Radioautographic studies to determine the proportion of cells in different phases of the mitotic cycle that incorporate tritiated thymidine during a single brief exposure to this precursor of DNA. 4. Estimation of the rate of incorporation of tritiated thymidine at different times during the period of DNA synthesis by comparison of mean grain counts over nuclei in radioautographs at different times following exposure to tritiated thymidine. The assumptions underlying these experiments and our observations concerning the duration of the period of DNA synthesis and its relation to the mitotic cycle are discussed. It is concluded that DNA synthesis is continuous, occupying a period of 8.5 hours during the interphase and that the average rate of synthesis is approximately constant.     

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.     

DNA synthesis in the embryonic chick central nervous system

Summary DNA synthesis has been studied in chick embryos age between 2 and 10 days, using labelling with tritiated thymidine and stripping film autoradiography. The observations made earlier in the literature on a premitotic migration of the nuclei in the neural epithelium have been verified. In young stages (before day 7) peripherally migrated cells do not synthesize DNA, but after day 7 such a synthesis occurs. In spite of this, few mitoses are seen. The interpretation of these facts is discussed.The costs of this investigation were defrayed by grants from the Swedish Medical Research Council, the Medical Faculty of Lund, and the Royal Physiographic Society.     

Deoxyribonucleic Acid synthesis in root cap cells of cultured roots of convolvulus

Isolated cultured roots of Convolvulus arvensis L. were incubated in 0.2 microcurie per milliliter methyl-³H-thymidine for 14 hours, for 64 hours, or for 14 hours followed by transfer to fresh nutrient medium without tritiated thymidine. Autoradiographs of serial, longitudinal sections of roots which were continuously incubated with tritiated thymidine showed that cells of the root cap columella did not undergo DNA synthesis after their formation from the root cap initials. In roots pulse-labeled with tritiated thymidine, the movement of labeled cells through the root cap columella was followed. Labeled cells were displaced at a constant rate of 72 microns per day over a period of 6 to 9 days before they were sloughed off from the root cap. The specialized role of the root cap cells in relation to their distinctive metabolism and longevity is discussed.     

Terminal differentiation of yolk-sac erythroid cells of the Syrian hamster in vitro

Summary The developmental fate of Syrian hamster yolk-sac (primitive) erythroid cells was examined in vitro. Highly purified yolk-sac erythroid cells at the polychromatophilic stage, obtained from the peripheral blood of embryos at day 10 of gestation, showed morphological and biochemical changes in our modified semi-solid culture system. Several morphological changes observed in the primitive erythroid cell cultures, such as nuclear condensation, approach of nuclei to the periphery of cells, development by cells of an extended pear-like shape, enucleation, and an increase in haemoglobin content, were quite similar to those of the terminal differentiation of fetal liver or adult bone marrow (definitive) erythroid cells. In addition, the transition of molecular species of haemoglobin from the embryonic to the fetal/adult pattern was also observed in our culture system. Thus we provide evidence, by the in vitro culture of yolk-sac erythroid cells, that primitive erythroid cells undergo terminal differentiation in a manner similar to that of definitive erythroid cells.     

DEVELOPMENTAL CHANGES OF ERYTHROPOIESIS IN CULTURED CHICK BLASTODERMS

The erythropoietic area of very early chick embryos was cultured as a tissue for up to nine days to study the changes in red cell type and hemoglobin type, the cell cycle time, the cell population kinetics, and the DNA synthetase activity of these cells. It was found that the area vasculosa without the participation of the embryo proper contained the information and the timing mechanism required to produce not only the early primitive erythroid cell population, but also in due course, the later definitive cell type, each with its appropriate hemoglobin types. Also the precursors of the definitive cell type are active in DNA synthesis and therefore are probably in cycle very early in the culture period.     

The development of chick spinal cord in tissue culture. II. Cultures of whole chick embryos

By using whole-chick-embryo cultures followed by fragment cultures of spinal-cord primordia, it was possible to reproduce in vitro the whole process of neuronal development beginning with its initiation and continuing up to and including the maturation of neurons. Normal whole embryos were developed to Hamilton-Hamburger stages 17 and 18 by growing embryos from the primitive streak stage on large (28-mm) glass rings. The advantage of whole-embryo cultures is that development can be staged accurately, which is especially important during the early stages when morphogenesis progresses very rapidly. By using such accurately staged embryos and tritiated thymidine, we have determined that some postmitotic neuronal precursor cells appear in chick embryos as early as Hamburger-Hamilton stages 4 and 5, i.e. the definitive streak stages before the neural tube has formed.     

In vitro technique for studying garter snake (Thamnophis sp.) development

Garter snake (Thamnophis sp.) embryos of different embryonic ages were explanted from pregnant females and grown in vitro for up to 35 days. The culture medium consisted of Eagle's Minimum Essential Medium with various organic and inorganic supplements and antibiotics. Cultured embryos were injected with tritiated thymidine, sacrificed, and processed for autoradiographic examination. The in vitro technique allowed direct visualization of external morphologic changes over time, which followed a timetable similar to that of embryos growing in vivo. This technique also allowed easier manipulation of embryos for determination of embryonic stage and for injection of tritiated thymidine. This is the first report of long-term culture of snake embryos which adds to the limited number of reptilian embryos that have been studied in vitro.     

Tritiated thymidine effects on DNA, RNA, and protein synthetic rates in synchronized L-cells

Exponentially growing L -cells were synchronized by the double thymidine-block method and exposed to high specific activities of tritiated thymidine. DNA, RNA, and protein synthetic rates were measured through one cell cycle with 1-hour pulses of the appropriate C¹⁴-labelled precursors. Equivalent doses of tritiated water were substituted for tritiated thymidine in some experiments. Total amounts of DNA and histones per nucleus were determined photometrically in Feulgen and fast-green stained cells. It was observed that incorporated tritiated thymidine has an effect distinct from that of tritiated water and that it enhances the incorporation of the precursors at specific stages of the cell cycle, to a degree roughly proportional to the dose. Photometric data indicated an increase in DNA net synthesis and a metabolic instability of histones in the H³-thymidine-treated cells, resulting in higher DNA:histone ratios.     

DNA synthesis rate and unlabeled cells with S-phase DNA content in P388 leukemic cells in vivo studied by flow cytometry and cell sorting

DNA synthesis kinetics of P388 leukemic cells growing in ascites form in BDF1 hybrid mice were investigated during the periods of exponential growth and growth restriction. Incorporation of tritiated thymidine, and in some instances tritiated uridine, was studied by autoradiography in cells sorted from S-phase fractions during DNA flow cytometry. During exponential growth continuous labeling with tritiated thymidine indicated a growth fraction of unity, whereas the growth fraction was about 30% during growth restriction. At this growth phase the majority of cells with S phase DNA content remained unlabeled after pulse labeling with tritiated thymidine or uridine, indicating that both the "salvage" and the "de novo" DNA synthesis pathways were blocked in most S-phase cells. After pulse labeling with tritiated thymidine the DNA synthesis rate pattern was investigated by sorting of consecutive fractions of cells throughout the S phase followed by quantitative autoradiography. With exception of a reduced rate in the middle of S phase, the DNA synthesis rate increased as the cells progressed through S phase during exponential growth. In contrast, the DNA synthesis rate pattern had a relative peak in the middle of S phase during growth restriction, which is otherwise characterized by a low mean DNA synthesis rate.     

The Measurement of Cell Turnover Rates Using Stable Isotope-Labelled Thymidine: Experiments On the Small Intestine and On A Transplantable Lymphatic Tumour of the Mouse

Multilabelled, non-radioactive thymidine and tritiated thymidine were incorporated simultaneously into the DNA of a rapidly-growing, transplantable mouse lymphoma and the DNA of mouse small intestine by a single intraperitoneal injection of both labelled nucleosides. Mice were killed at selected times during the next 7 days, and the specific activities of the tissues and extracted DNA and the 132/126 mass ratio of thymine isolated from the DNA were determined by scintillation counting and by field ionization mass spectrometry respectively. the rates of decrease of the concentrations of tritiated and stable isotope-labelled thymine in the DNA of the tumour or of the intestine were essentially identical. These results indicate the feasibility of using thymidine multilabelled with stable isotopes for measurement of cell turnover rates in conjunction with cancer therapy.     

Ontogenetic changes of circulating erythroid cells and haemoglobin components in Esox lucius

Using light microscopy the morphology, the mitotic index and levels of erythroid cell types were detected from 48 h pike Esox lucius embryos before hatching to adult specimens. At the same developmental stages, the haemoglobins and globin chains expressed were electrophoretically characterized. The erythroid cells of the primitive generation were the most abundant from 48 h before hatching until 15–20 days after hatching, then their number decreased and only rare cells remained in the 3 month‐old juvenile specimens. These cells divided and differentiated in the blood and were substituted by the definitive erythrocyte series. As in other vertebrates, the immature cells of the two generations differed in morphological properties and in the synthetized haemoglobin. The circulating erythroid cells of the definitive population cell lineage were, at all differentiation stages, smaller than those of the primitive generation. The definitive erythrocytes appeared in blood smears of 7 days post‐hatching larvae, they increased rapidly and at 20 days they represented the predominant red blood cell population in the circulation of young pike. Electrophoretic analysis of haemolysates obtained from different developmental stages indicated the presence of distinct embryonic, larval and adult haemoglobins. The embryonic haemoglobins differed from those of the older larva and juvenile specimens and were detectable within the first week of post‐hatching development when only primitive erythrocytes were present in the blood.     

The measurement of cell turnover rates using stable isotope-labelled thymidine: experiments on the small intestine and on a transplantable lymphatic tumour of the mouse.

Multilabelled, non-radioactive thymidine and tritiated thymidine were incorporated simultaneously into the DNA of a rapidly-growing, transplantable mouse lymphoma and the DNA of mouse small intestine by a single intraperitoneal injection of both labelled nucleosides. Mice were killed at selected times during the next 7 days, and the specific activities of the tissues and extracted DNA and the 132/126 mass ratio of thymine isolated from the DNA were determined by scintillation counting and by field ionization mass spectrometry respectively. The rates of decrease of the concentrations of tritiated and stable isotope-labelled thymine in the DNA of the tumour or of the intestine were essentially identical. These results indicate the feasibility of using thymidine multilabelled with stable isotopes for measurement of cell turnover rates in conjunction with cancer therapy.     

The incorporation of 5-bromodeoxyuridine into DNA of the area opaca vasculosa of chick embryos

The incorporation of 5-bromodeoxyuridine (5-BrdUrd) into DNA of the area opaca vasculosa (AOV) of chick embryos during organ culture was measured. The AOV from blastoderms of the definitive primitive streak stage will not form red cells in the presence of BrdUrd while the AOV of 1–3 somite blastoderms is unaffected by the presence of 5-BrdUrd. About 90% of the original non-density labeled DNA can replicate in the presence of 5-BrdUrd if the tissues come from the younger sensitive embryos, but only 65% of the original DNA will replicate from tissues of older insensitive embryos. Tissues from embryos of both ages replace about 80% of the thymidine by BrdUrd in each newly synthesized strand of DNA; tissues from embryos of both ages will form DNA of hybrid density after one cell generation, and will also form double-heavy DNA after longer periods of culture in the presence of 5-BrdUrd. During recovery from 5-BrdUrd inhibition during a thymidine chase, the density-labeled DNA is replicated so that the new DNA of normal density is formed, but the original heavy 5-BrdUrd containing strands are conserved. It is suggested that inhibition of red cell formation by 5-BrdUrd may occur by incorporation of 5-BrdUrd into DNA of endoderm cells, rather than by acting only directly on red cell precursors.     

Quantitative aspects of the cell cycle in the cranial neural tube of the rhesus monkey (Macaca mulatta) during early stages of gestation

The generation time of ventricular cells in the cranial neural tube of the rhesus monkey embryo was estimated by means of tritiated thymidine autoradiography at stages 12, 13, and 14 (25-31 d of gestation) relative to that which occurs in the mouse at corresponding stages of development. In the rhesus monkey embryo, the generation time lengthens between stages 12 and 13 of gestation, as is the case in the mouse at comparable stages. However, the generation time in rhesus monkey embryos at stage 13 appears to be longer than that in comparable mouse embryos at 10 days of gestation. Thus, it is possible that temporal differences may occur between the rhesus monkey embryo and mouse embryo in terms of the response of the cranial neuroepithelium to teratogenic insults involving the cell cycle.