Accessory nuclei of the primary erythroid cells of chick embryos: the kinetics of their formation and the relationship to the synthesis of extra DNA

Kinetics of formation of accessory nuclei (AN), synthesis and accumulation of DNA in AN and main nuclei (MN) of the chick embryo primary erythroid cells (PEC) (2-7 days of development) and interdependence of these processes were studied using cytomorphology, autoradiography and differential cytophotometry. The earlier data on the existence of AN in primary erythrocytes (EC) were confirmed, and it was shown for the first time that the formation of AN accompanied the primary erythropoiesis from the very beginning of the proerythroblast (PEB) stage. The number of AN-bearing cells increases as erythropoiesis proceeds to reach the value of 50% PEC. The AN are formed in diploid, tetraploid, as well as in binuclear cells. The DNA content in AN may vary from 1-2 to 80% of the 2c value and has a tendency of increasing during erythropoiesis, while that in MN is always 2c or multiple thereof. Formed at early stages of PEC proliferation as pieces of segregated Feulgen-positive material, the AN are preserved during mitosis, taking no part in mitotic rearrangements of the chromosomes and being eventually involved in one of the daughter cells. Clusters of metaphase, anaphase and telophase chromosomes contain strictly 4c or 2c + 2c DNA. DNA synthesis in MN and AN may proceed in parallel and independently. It is frequently observed in AN of terminally differentiated PEC-reticulocytes (RC) and EC, whose MN no longer incorporate 3H-thymidine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differentiation pathways of primary erythroid cells in chickens

Proliferation and differentiation processes of chick embryo primary erythroid cells (PEC) were studied. A novel differentiation pathway was discovered by which cells of proerythroblastic and erythroblastic stages are blocked in G1 or G2 phases, to develop then directly into reticulocytes, i.e. terminally differentiated non-dividing cells with high hemoglobin contents differing in shape from erythrocytes. These cells appear in blood two days earlier than erythrocytes, then they co-exist with the latter and are eliminated in parallel with them. This pathway leads to a rapid enrichment of PEC with hemoglobin. A fraction of PEC forms accessory nuclei, which, as it is shown here, contain an extra quantity of DNA. Compared to the diploid ones, such cells reveal increased hemoglobin contents which enabled us to assume that they may have amplified the globin genes. The above-mentioned pecularities of cytodifferentiation may be presumably an adaptation to oxygen supply of growing embryos which are known to stay in hypoxia. A comparison of these results with results of our earlier study on experimental anemia makes it possible to suppose that pecularities of these two types of cytodifferentiation may be based on similar or, perhaps, analogous mechanisms of regulation.     

DNA content of the nuclei of secondary giant cells of the rat trophoblast at different phases of the polytene nucleus cycle

A cytophotometric study of DNA content has been made for secondary trophoblastic giant cells, which differ morphologically in relation to the stage of the cycle of the polytene nucleus. The ploidy rate varying from 16c to 512c. It is shown that the DNA content of the nuclei with polytene chromosomes in phase G is more stable, corresponding to the 2c multiple DNA content. Unlike, reticular nuclei in phase S do not present clear-cut peaks on a histogram of DNA. Ratios of nuclei with unequal ploidy differ depending on the structure of these nuclei.     

NUCLEAR DNA CONTENT OF EMBRYONIC RADICLES AND CULTURED STATIONARY PHASE ROOT TIPS OF PEA (PISUM SATIVUM L.)

Cells in mature embryos and stationary phase (SP) root meristems of pea arrest in G1 and G2 of the cell cycle. The patterns of distribution of G2 nuclei in radicles and SP meristems, with and without G2 factor, were compared by using cytophotometric analysis of the relative amount of DNA/nucleus in sectioned material. Radicles and SP meristems were each divided into 5 zones and the ratio of G1 to G2 nuclei was determined for each zone. The G2 population in the radicle is restricted mainly to the embryonic cortex. A small part of the G2 population was located in the central cylinder and the root cap. In SP meristems without G2 factor, the pattern of distribution of G2 cells was similar to that in radicles. SP meristems with G2 factor contained G2 arrested nuclei in all regions of the root tip. In each region the percentage of G2 nuclei was higher than that in the same region of SP meristems without G2 factor. This indicates that the population of cells that responds to G2 factor is distributed throughout the root tip.     

Initiation of DNA replication in nuclei from quiescent cells requires permeabilization of the nuclear membrane

We have investigated the replication capacity of intact nuclei from quiescent cells using Xenopus egg extract. Nuclei, with intact nuclear membranes, were isolated from both exponentially growing and contact- inhibited BALB/c 3T3 fibroblasts by treatment of the cells with streptolysin-O. Flow cytometry showed that > 90% of all contact- inhibited cells and approximately 50% of the exponential cells were in G0/G1-phase at the time of nuclear isolation. Intact nuclei were assayed for replication in the extract by incorporation of [alpha- 32P]dATP or biotin-dUTP into nascent DNA. Most nuclei from exponential cells replicated in the egg extract, consistent with previous results showing that intact G1 nuclei from HeLa cells replicate in this system. In contrast, few nuclei from quiescent cells replicated in parallel incubations. However, when the nuclear membranes of these intact quiescent nuclei were permeabilized with lysophosphatidylcholine prior to addition to the extract, nearly all the nuclei replicated under complete cell cycle control in a subsequent incubation. The ability of LPC-treated quiescent nuclei to undergo DNA replication was reversed by resealing permeable nuclear membranes with Xenopus egg membranes prior to extract incubation demonstrating that the effect of LPC treatment is at the level of the nuclear membrane. These results indicate that nuclei from G1-phase cells lose their capacity to initiate DNA replication following density-dependent growth arrest and suggest that changes in nuclear membrane permeability may be required for the initiation of replication upon re-entry of the quiescent cell into the cell cycle.     

Cytophotometric analysis of corresponding cytological and histological cervical intraepithelial neoplasia grade III specimens

Cytophotometric analysis of cervical intraepithelial neoplasia grade III (CIN III) was performed in 22 cytological smears (CS) and in 22 corresponding cytospin specimens retrieved from selected areas of paraffin-embedded tissues (PEC). The average time interval between cytological and histological diagnosis was 6 weeks. CIN III nuclei in CS and PEC specimen were Thionin-Feulgen stained and digitized. Beside the visual classification of DNA ploidy patterns, the 2.5c and 5c exceeding rates and the specimen mean and standard deviation values of 21 photometric features were also analyzed. It was shown that, although there was a significant correlation between DNA ploidy patterns in corresponding PEC and CS specimen, the DNA patterns were dissimilar in eight of 22 cases. The DNA index, as represented by 2.5c and 5c exceeding rates, was significantly higher in the CS specimen. High-resolution cytophotometric analysis of cell nuclei in CS and PEC specimens showed significant differences for a large number of nuclear photometric features. These findings can possibly be explained by differences in selection of CIN III cells from CS and PEC specimens and by differences between fixation procedures as used for the two techniques. It was concluded that cytophotometric data of CS and PEC specimens representing CIN III lesions should not be regarded as interchangeable.     

The effect of topoisomerase inhibitors on the expression of differentiation markers and cell cycle progression in human K-562 leukemia cells.

Treatment of human K-562-J leukemia cells for 1 h with the topoisomerase II-reactive drugs VP-16, VM-26, or mAMSA resulted in a dose-dependent inhibition of proliferation and in an increase in the percentage of cells staining positive for hemoglobin, a marker of erythroid differentiation. Staining for hemoglobin of up to about 60% of the cells was observed at 20 microM VP-16, 1 microM VM-26, and 8 microM mAMSA. Such treatment also caused a G2/M arrest in the cell cycle. Incubation of the cells with radiolabeled VP-16 indicated that the induced erythroid differentiation was not due to continuous cell exposure to a residual amount of the drug. VP-16-induced erythroid differentiation was also not affected by DNA, RNA, or protein synthesis inhibitors. Differentiation induction and the G2/M arrest evoked by VP-16, VM-26, and mAMSA were, however, reduced in the presence of novobiocin. Our results indicate that topo-reactive drugs that cause G2/M arrest in the K-562-J cell cycle can induce in these cells erythroid differentiation after a short and irreversible interaction with their target molecule(s).     

Specific nuclear elimination in polyploid plasmodia of the slime mold Physarum polycephalum

In growing plasmodia of the myxomycete Physarum polycephalum (G2-phase), three distinct classes of nuclei with a relative DNA content of 1x, 2x, and 4x are observed in the presumed haploid strain CL. The 2x and 4x species comprise up to 35% and 5% of the nuclei. Quantitative cytofluorometric studies of nuclei isolated in either G2- or S-phase or after FUDR treatment (G1 arrest) show that the three nuclear populations undergo a synchronous mitotic cycle and that the relative DNA content of the nuclear fractions in G-2 phase reflects the 2c, 4c, and 8c state. The heterogeneity of the nuclear population does, however, seem to be restricted to the growth phase. During a starvation period of 4 days that always preceeds sporulation (and also meiosis), the 4c nuclear population is reduced to 7%, 8c nuclei are no longer detected. These results suggest that a mechanism exists in Physarum for the selective detection and elimination of polyploid nuclei.     

Characteristic alteration in the nuclear DNA polymerase activity during the cell division cycle of Saccharomyces cerevisiae

Specific activity of the intranuclear DNA polymerase in cdc-mutant cells of Saccharomyces cerevisiae was found to be characteristically changed by arrest in their specific stage of cell division cycle without a notable alteration in the total cellular activity. The activities were low in the nuclei of cdc 25, cdc 28 and cdc 4, which were arrested in early to mid G1 phase by temperature shift-up, and in the nuclei of wild-type cells (A364A), which were arrested in early G1 phase by alpha-factor treatment, while high level of the activity was found in the nuclei of cdc 7 and cdc 8, which were arrested at late G1 and S phase, respectively. Activity-gel analysis of DNA polymerase in the nuclear extracts revealed the presence of two active peptides (120K and 72K), and the characteristic decrease in both active peptides was induced by arrest in early to mid G1 phase. Consequently, it is strongly suggested that intranuclear DNA polymerase activity alters in a dependent fashion on progression of cell division cycle. Subunit analysis indicated that the purified DNA polymerase I is constructed from two subunit peptides of 120K and 62K, and the large subunit possesses catalytic activity.     

Cytophotometric analysis of the cell population composition of the the preoptic area of the hypothalamus in the common frog

DNA contents in squashed cells of the adult frog hypothalamic preoptic region (HPR) were measured using the Feulgen and UV cytophotometry techniques. The histone-DNA ratio in the cell nucleus was determined by means of a combined Feulgen-heparin-Alcian blue staining procedure. The nuclei of the vast majority of HPR cells have a diploid DNA content. However, in cells of this group the mean values of DNA amount and the distribution range were always higher than those in hepatocytes used as a diploid standard. Such a heterogeneity in DNA content in the diploid part of HPR cell population could apparently suggest some differences in the nuclear chromatin arrangement to be always higher in spring before the frog spawning, and it seems to be characteristic of this type of cells. About 1 per cent of cells with hyperdiploid surplus of DNA (H2c cells) as well as of tetraploid cells (4c and 2c X 2 cells) is found in HPR in frogs sacrificed both in winter and in summer. The quota of these cells has no reference either to the frog's age or to the annual cycle. The fact that the mean DNA values in H2c and 4c cells are much higher than in the standard cannot be explained by the presence of different amounts of nuclear proteins only. It is suggested that at least some part of the highest DNA values may be due to an actual extra DNA synthesis in a small constantly existing pool of HPR cell population.     

Simian Virus 40-Host Cell Interaction During Lytic Infection

Both exponentially growing and serum-arrested subcloned CV-1 cell cultures were infected with simian virus 40 (SV40). By 24 h after infection 96% of the nuclei of these permissive cells contained SV40 T-antigen. Analysis of the average DNA content per cell at various times after infection indicated that by 24 h most of the cells contained amounts of DNA similar to those normally found in G(2) cells. Analysis of cell cycle distributions indicated that a G(2) DNA complement was maintained by over 90% of the cells in the infected populations 24 to 48 h postinfection. Cells continued to synthesize SV40 DNA during the first 50 h after infection, and cytopathic effect was first observed 60 h after inoculation. After infection the number of mitotic cells that could be recovered by selective detachment decreased precipitously and was drastically reduced by 24 h. A study of the kinetics of decline in the number of mitotic cells suggests that this decline is related to an event during the cell cycle at or near the G(1)-S-phase border upon which commencement of SV40 DNA replication apparently depends. It was concluded that after SV40 infection, stationary cells are induced to cycle, and cycling cells complete one round of cellular DNA synthesis but do not divide. Although the infected cells continue to synthesize viral DNA, they do not appear able to reinitiate cellular DNA replication units. These results imply that the abundance of T-antigen (produced independently of cell cycle phase) in the presence of the enzymes required for continued DNA synthesis is not sufficient for reinitiation of cellular DNA synthesis.     

Block to DNA replication in meiotic maturation: a unified view for a robust arrest of cell cycle in oocytes and somatic cells

Under certain conditions, the cell cycle can be arrested for a long period of time. Vertebrate oocytes are arrested at G(2) phase, while somatic cells arrest at G(0) phase. In both cells, nuclei have lost the ability to initiate DNA synthesis. In a pair of recently published papers,[1,2] Méchali and colleagues and Coué and colleagues have clarified how frog oocytes prevent untimely DNA synthesis during the long G(2) arrest. Intriguingly, they found only Cdc6 is responsible for the inability of immature oocytes to replicate DNA. Cdc6 is a key component for replication licensing, and for G(0) cells to re-enter the proliferative stage. Strikingly similar strategies for preventing the untimely replication in both cells suggest that the suppression of replication licensing is a universal mechanism for securing the prolonged arrest of the cell cycle.     

Microphotometry of rat liver nucleoproteins during the cell cycle, and comparison of diploid nuclei in the G2 period with tetraploid nuclei.

The following facts were established with a microphotometric investigation of isolated nuclei from rat liver in different stages of the cell cycle. During the mitotic wave occurring in the liver of newborn animals after injection of casein it was found that the naphtol yellow S (NYS) protein content of the nuclei increases about 30% during the G1-period. A second increase of around 70% was established during the S-phase whereas no increase could be observed during the G2-phase. An indication for the existence of a "critical protein mass" of the nuclei before the onset of the S-phase could be observed. The protein content of diploid nuclei in the G1-phase of adult animals is about 50% higher than in newborns. This makes it probable that there is no significant difference in the NYS-protein content of diploid nuclei in the G2-period and tetraploid nuclei of adult rats. No differences were observed between diploid nuclei in the G2-period of newborn rats and tetraploid nuclei of adult rats in their Fastgreen histon, RNA and SH plus SS content. The only criterion to distinguish between G2 nuclei and tetraploid nuclei seems to be the number of nucleoli, but this is rather unreliable.     

Radiation dose-dependent maintenance of G(2) arrest requires retinoblastoma protein

In response to ionizing radiation (IR), cell cycle checkpoints are activated to provide time for DNA repair. Several different checkpoint mechanisms have been elucidated. However, mechanisms that regulate the duration of cell cycle arrest are not understood. Previous studies have shown that the retinoblastoma tumor suppressor protein (RB) is required for radiation-induced G1 arrest. Working with primary fibroblasts derived from Rb+/+ and Rb-/- mouse embryos, we show that RB also regulates the duration of G2 arrest. The initial G2 checkpoint response is enhanced in Rb-/- cells due to a defect in G1 arrest. However, the permanent arrest in G2 induced by higher doses of IR does not occur in Rb-/- cells. Rb-/- cells either resumed proliferation or underwent apoptosis at IR doses that caused the majority of Rb+/+ cells to arrest permanently in G2. The prolongation of G2 arrest in Rb+/+ cells correlated with a gradual accumulation of hypophosphorylated RB. Thus, regulation of the RB function may be an important aspect in the maintenance of cell cycle checkpoints in DNA damage response.     

Radiation Dose-Dependent Maintenance of G2 Arrest Requires Retinoblastoma Protein

In response to ionizing radiation (IR), cell cycle checkpoints are activated to provide time for DNA repair. Several different checkpoint mechanisms have been elucidated. However, mechanisms that regulate the duration of cell cycle arrest are not understood. Previous studies have shown that the retinoblastoma tumor suppressor protein (RB) is required for radiation-induced G1 arrest. Working with primary fibroblasts derived from Rb+/+ and Rb-/- mouse embryos, we show that RB also regulates the duration of G2 arrest. The initial G2 checkpoint response is enhanced in Rb-/- cells due to a defect in G1 arrest. However, the permanent arrest in G2 induced by higher doses of IR does not occur in Rb-/- cells. Rb-/- cells either resumed proliferation or underwent apoptosis at IR doses that caused the majority of Rb+/+ cells to arrest permanently in G2. The prolongation of G2 arrest in Rb+/+ cells correlated with a gradual accumulation of hypophosphorylated RB. Thus, regulation of the RB function may be an important aspect in the maintenance of cell cycle checkpoints in DNA damage response.

Key Words:

RB phosphorylation, Ionizing radiation, DNA damage, G2 checkpoint, Mouse embryo fibroblasts     

HIV-1 Vpr induces G2 cell cycle arrest in fission yeast associated with Rad24/14-3-3-dependent, Chk1/Cds1-independent Wee1 upregulation

Viral protein R (Vpr), an accessory protein of human immunodeficiency virus type 1 (HIV-1), induces the G2 cell cycle arrest in fission yeast for which host factors, such as Wee1 and Rad24, are required. Catalyzing the inhibitory phosphorylation of Cdc2, Wee1 is known to serve as a major regulator of G2/M transition in the eukaryotic cell cycle. It has been reported that the G2 checkpoint induced by DNA damage or incomplete DNA replication is associated with phosphorylation and upregulation of Wee1 for which Chk1 and Cds1 kinase is required. In this study, we demonstrate that the G2 arrest induced by HIV-1 Vpr in fission yeast is also associated with increase in the phosphorylation and amount of Wee1, but in a Chk1/Cds1-independent manner. Rad24 and human 14-3-3 appear to contribute to Vpr-induced G2 arrest by elevating the level of Wee1 expression. It appears that Vpr could cause the G2 arrest through a mechanism similar to, but distinct from, the physiological G2 checkpoint controls. The results may provide useful insights into the mechanism by which HIV-1 Vpr causes the G2 arrest in eukaryotic cells. Vpr may also serve as a useful molecular tool for exploring novel cell cycle control mechanisms.     

Digital Holographic Microscopy for Non-Invasive Monitoring of Cell Cycle Arrest in L929 Cells

Digital holographic microscopy (DHM) has emerged as a powerful non-invasive tool for cell analysis. It has the capacity to analyse multiple parameters simultaneously, such as cell- number, confluence and phase volume. This is done while cells are still adhered and growing in their culture flask. The aim of this study was to investigate whether DHM was able to monitor drug-induced cell cycle arrest in cultured cells and thus provide a non-disruptive alternative to flow cytometry. DHM parameters from G1 and G2/M cell cycle arrested L929 mouse fibroblast cells were collected. Cell cycle arrest was verified with flow cytometry. This study shows that DHM is able to monitor phase volume changes corresponding to either a G1 or G2/M cell cycle arrest. G1-phase arrest with staurosporine correlated with a decrease in the average cell phase volume and G2/M-phase arrest with colcemid and etoposide correlated with an increase in the average cell phase volume. Importantly, DHM analysis of average cell phase volume was of comparable accuracy to flow cytometric measurement of cell cycle phase distribution as recorded following dose-dependent treatment with etoposide. Average cell phase volume changes in response to treatment with cell cycle arresting compounds could therefore be used as a DHM marker for monitoring cell cycle arrest in cultured mammalian cells.     

On the kinetics of erythroid cell differentiation in fetal mice. I. Microspectrophotometric determination of the hemoglobin content in erythroid cells during gestation

In a microspectrophotometric study, photographic emulsions and a computer are used for measuring the hemoglobin content of a large number (about 50,000) of erythroid cells in fetal mice. Histograms of the hemoglobin content in erythroid cells illustrate the kinetics of erythropoiesis in yolk sac derived nucleated cells in the fetal peripheral blood, in fetal liver, and in fetal spleen. After the occasional extrusion of their nucleus, yolk sac derived erythrocytes remain as “macrocytes” in fetal circulation two or three days longer than the nucleated yolk sac derived erythrocytes do. Erythrocytes in fetal liver have a constant hemoglobin content of 28 pg ² until day 17 of gestation. During further erythropoiesis in liver and then in the spleen, this amount is gradually adapted to the normal hemoglobin content in red blood cells of 16 pg.     

Induction of M-phase arrest and apoptosis after HIV-1 Vpr expression through uncoupling of nuclear and centrosomal cycle in HeLa cells

The human immunodeficiency virus type 1 (HIV-1) accessory protein Vpr induces cell cycle arrest in the G2 phase of the cell cycle followed by apoptosis. The mechanism of the arrest is unknown but the arrest is believed to facilitate viral replication. In the present study, we have established cell lines that allow conditional expression of Vpr, and have examined the mechanism of cell death following Vpr expression. We found that cells expressing Vpr enter M phase after long G2 arrest but formed aberrant multipolar spindles that were incapable of completing karyokinesis or cytokinesis. This abnormality provided the basis for apoptosis, which always followed in these cells. The multipolar spindles formed in response to abnormal centrosomal duplication that occurred during the G2 arrest but did not occur in cells arrested in G2 by irradiation. Thus, the expression of Vpr appears to be responsible for abnormal centrosome duplication, which in turn contributes in part to the rapid cell death following HIV-1 infection.