Chronology and pattern of replication in the bone marrow chromosomes of Gallus domesticus

The duration of the cell generation, the chronology, and the pattern of chromosome duplication was studied in the bone marrow of Gallus domesticus. The duration of the phases of the cell cycle is: cell generation 17.5 hours, S period 9 hours. G₂ period plus prophase stage 2.5 hours, G₁ period 6 hours. Chromosome replication begins at many sites. During middle S it extends to the whole complement and finally finishes in small, late replicating regions of the macrochromosomes. Interchromosomal asynchrony of duplication at the initiation or at the end of the S period was not observed. Z-chromosomes begin and finish DNA synthesis synchronously with the other macrochromosomes. The W-chromosome in females is the last microchromosome to finish replication. However it ends DNA synthesis at about the same time as the macrochromosomes. Similarities and differences between chromosome replication in Aves and Mammalia are considered.     

Estrogen receptor alpha is cell cycle-regulated and regulates the cell cycle in a ligand-dependent fashion

Estrogen receptor alpha (ERα) has been implicated in several cell cycle regulatory events and is an important predictive marker of disease outcome in breast cancer patients. Here, we aimed to elucidate the mechanism through which ERα influences proliferation in breast cancer cells. Our results show that ERα protein is cell cycle-regulated in human breast cancer cells and that the presence of 17-β-estradiol (E2) in the culture medium shortened the cell cycle significantly (by 4.5 hours, P < 0.05) compared with unliganded conditions. The alterations in cell cycle duration were observed in the S and G₂/M phases, whereas the G₁ phase was indistinguishable under liganded and unliganded conditions. In addition, ERα knockdown in MCF-7 cells accelerated mitotic exit, whereas transfection of ERα-negative MDA-MB-231 cells with exogenous ERα significantly shortened the S and G₂/M phases (by 9.1 hours, P < 0.05) compared with parental cells. Finally, treatment of MCF-7 cells with antiestrogens revealed that tamoxifen yields a slower cell cycle progression through the S and G₂/M phases than fulvestrant does, presumably because of the destabilizing effect of fulvestrant on ERα protein. Together, these results show that ERα modulates breast cancer cell proliferation by regulating events during the S and G₂/M phases of the cell cycle in a ligand-dependent fashion. These results provide the rationale for an effective treatment strategy that includes a cell cycle inhibitor in combination with a drug that lowers estrogen levels, such as an aromatase inhibitor, and an antiestrogen that does not result in the degradation of ERα, such as tamoxifen.     

The duration of DNA synthetic (S) period in Zea mays: A genetic control

Summary The nuclear cycle among several diverse genetic stocks of Zea mays root meristem cells was compared and it was found that there were no significant differences among the nuclear cycle durations and its component phases. The durations of various periods of their mitotic cycles were studied by autoradiography of cells pulse-labelled with tritiated thymidine (3H-TdR). The total nuclear cycle was 10 to 11.5 hours and mitosis was 0.81 to 1.34 hours at 25°C. The S period is the longest interval (50% of the total time) of the nuclear cycle; of the rest of the cycle, G₂ is longer than G₁ or mitosis among all stocks. The constancy of the nuclear cycle among several stocks was adduced as evidence for strict genetic control of the cycle. Furthermore, it is demonstrated the DNA synthesis period is not dependent upon the amount of DNA present.This study is based on a portion of the dissertation presented by the senior author to the Graduate School, The University of Western Ontario, London, Canada, in partial fulfillment of the requirement for the Ph. D. degree     

Timing and Regulation of Nuclear and Cortical Events in the Cell Cycle of Tetrahymena pyriformis*

SYNOPSIS. Using continuous flow cultures based on the chemostat principle, we varied the cell generation times of the ciliate Tetrahymena pyriformis strain GL, from 4.9 to 22.2 hr and studied various parameters of the cell cycle at 28 C. These included: the duration of the periods required for oral morphogenesis, macronuclear division, cell division, G₁ S, and G₂. The size of individual cells was also measured. Independent of the growth rate, the period of oral morphogenesis occurred during the last 90 min of the cell cycle. In all cases macronuclear and cell divisions took place during the last part of these 90 min, and the final macronuclear separation occurred just before final cell separation. The S-period increased slightly, while the G₁ and G₂ both increased in roughly the same relative proportion to the increasing generation times. Slowly growing cells (generation time 20.5 hr) were shorter but broader and somewhat larger in volume than quickly growing cells (generation time 4.9 hr).     

Effects of 1000 R whole-body X-irradiation on DNA synthesis and mitosis in the duodenal crypts of the BCF1 mouse

Summary Effects of 1000 R, whole-body X-irradiation on the proliferative cells of the mouse duodenal crypts, in the four phases of the generation cycle; namely, the DNA synthesis phase, S; the pre-mitotic gap, G ₂; the division phase or mitosis, M; and the pre-synthesis gap, G ₁. As pointed out by Whitmore and Till (1964) G₁ and G₂ are characterized only by the fact that no DNA synthesis is taking place in these phases.In the intestinal crypts of BCF₁ mice, a 1000 R whole-body X-ray exposure blocks cells in G₂ for approximately 18 hours, and reduces the number of cells in S to less than 1/2 that observed in control animals during the first 12 hours after exposure. Cells synthesizing DNA, and undergoing division, remain few in number for more than 48 hours. Between 48 and 72 hours a compensatory reaction begins, and the number of cells in M and S increases from 28 at 48 hours to 150 at 72 hours and reaches a mean value of 482 at 96 hours.Work supported under the auspices of the US Atomic Energy Commission.     

PROLIFERATION KINETICS OF AN EXPERIMENTAL ASCITES TUMOUR OF THE MOUSE

The cell cycles of an experimental ascitic tumour of the C3H mouse (NCTC 2472) were determined at various times after the intraperitoneal injection of 10⁶ cells. It was found that, contrary to results in solid NCTC 2472 tumours, obtained with the same NCTC cells, the duration of the cell cycle and its phases lengthened with the age of the tumour while the growth fraction remained relatively constant. G₁ was the first phase to lengthen, while later T_s and T_G2 increased also. The amount of DNA per cell was determined by cytospectrophotometry. This method provides data on the evolution during growth of the relative number of cells in each phase of the cell cycle.     

Cell Cycle Dynamics of Cultured Coral Endosymbiotic Microalgae (Symbiodinium) Across Different Types (Species) Under Alternate Light and Temperature Conditions

Dinoflagellates of the genus Symbiodinium live in symbiosis with many invertebrates, including reef‐building corals. Hosts maintain this symbiosis through continuous regulation of Symbiodinium cell density via expulsion and degradation (postmitotic) and/or constraining cell growth and division through manipulation of the symbiont cell cycle (premitotic). Importance of premitotic regulation is unknown since little data exists on cell cycles for the immense genetic diversity of Symbiodinium. We therefore examined cell cycle progression for several distinct SymbiodiniumITS2‐types (B1, C1, D1a). All types exhibited typical microalgal cell cycle progression, G₁ phase through to S phase during the light period, and S phase to G₂/M phase during the dark period. However, the proportion of cells in these phases differed between strains and reflected differences in growth rates. Undivided larger cells with 3n DNA content were observed especially in type D1a, which exhibited a distinct cell cycle pattern. We further compared cell cycle patterns under different growth light intensities and thermal regimes. Whilst light intensity did not affect cell cycle patterns, heat stress inhibited cell cycle progression and arrested all strains in G₁ phase. We discuss the importance of understanding Symbiodinium functional diversity and how our findings apply to clarify stability of host‐Symbiodinium symbioses.     

Growth dynamics of an amphibian tissue

By the “labeled mitoses” method of Quastler and Sherman and others, the cell cycle of the germinative zone cells of the bullfrog lens epithelium has been characterized. It has been shown that this cycle lasts approximately 83 days with the DNA synthetic phase enduring 100 hours and G₂, 11 hours. G₁ occupies over 90% of the total time. the duration of mitosis itself has not been precisely determined. the length of the synthetic phase was corroborated by double labeling with c¹⁴ and h³-thymidine. When the temperature is raised by 6°c, from 24° to 30° the cycle is compressed by 40%. When the nongerminative, central cells of bullfrog lens epithelium are activated (stimulated to undergo DNA synthesis and mitosis) by injury or through in vitro culture, the length of the cycle also appears to decrease. in the in vitro experiments the generation time, as judged by the period elapsing between two successive bursts of DNA synthesis involving the same cells, amounts to 177–190 hours at 24°c. by raising the temperature to 30°c the time from injury or isolation until the appearance of the first wave of mitosis is reduced by 20%.     

Effect of serum step-down on protein metabolism and proliferation kinetics of NHIK 3025 cells

Human NHIK 3025 cells growing exponentially in 30% or 3% serum had population doubling times of 19.1 and 27.6 hours, respectively. These values were equal to the calculated protein doubling times (17.6 and 26.5 hours, respectively), showing that the cells were in balanced growth at both serum concentrations. Stepdown from 30% to 3% serum reduced the rate of protein synthesis within 1–2 hours, from 5.7% hour to 4.3% hour, while the rate of protein degradation was unchanged (1.7%/hour). In cells synchronized by mitotic selection from an exponentially growing population, the median cell cycle durations in 30% and 3% serum were 17.2 and 23.6 hours, respectively, which were also in good agreement with the protein doubling times. The median G₁ durations were 7.1 and 9.6 hours, respectively. Thus the duration of G₁ relative to the total cell cycle duration was the same in the two cases. Complete removal of serum for a period of 3 hours resulted in a 3-hour prolongation of the cell cycle regardless of the time after mitotic selection at which the serum was removed. For synchronized cells, the rate of entry into both the S phase and into the subsequent cell cycle were reduced in 3% serum as compared to 30% serum, the former rate being significantly greater than the latter at both serum concentrations. Our results thus indicate that these cells are continuously dependent upon serum throughout the entire cell cycle.     

EFFECTS OF NEAR ULTRAVIOLET AND VISIBLE RADIATIONS ON CELL CYCLE KINETICS IN EXCISED ROOT MERISTEMS OF PISUM SATIVUM

Near-ultraviolet and visible radiations increased the duration of the mitotic cycle in excised pea root meristems primarily by lengthening the duration of the pre-DNA synthetic period (G₁). All radiations tested shortened the duration of the post-DNA synthetic period (G₂). The most pronounced effects were exhibited by green radiation, which lengthened the duration of the cell cycle, G₁, DNA synthesis (S), and mitosis (M), and shortened the duration of G₂. Progression of cells arrested by starvation in G₁ and G₂ into DNA synthesis and mitosis was also affected by light treatments. Green radiation appeared to arrest a group of cells in DNA synthesis as well as in G₁ and G₂. Meristems receiving green and near-ultraviolet radiations exhibited the most rapid progression of G₁ cells through S and G₂.     

CELL POPULATION KINETICS OF EXCISED ROOTS OF PISUM SATIVUM

The cell population kinetics of excised, cultured pea roots was studied with the use of tritiated thymidine and colchicine to determine (1) the influence of excision, (2) the influence of sucrose concentration, (3) the average mitotic cycle duration, and (4) the duration of mitosis and the G₁, S, and G₂ periods of interphase.¹ The results indicate that the process of excision causes a drop in the frequency of mitotic figures when performed either at the beginning of the culture period or after 100 hours in culture. This initial decrease in frequency of cell division is independent of sucrose concentration, but the subsequent rise in frequency of division, after 12 hours in culture, is dependent upon sucrose concentration. Two per cent sucrose maintains the shortest mitotic cycle duration. The use of colchicine indicated an average cycle duration of 20 hours, whereas the use of tritiated thymidine produced an average cycle duration of 17 hours.     

Cell cycle arrest by prostaglandin A1 at the G1/S phase interface with up-regulation of oncogenes in S-49 cyc− cells

Our previous studies have implied that prostaglandins inhibit cell growth independent of cAMP. Recent reports, however, have suggested that prostaglandin arrest of the cell cycle may be mediated through protein kinase A. In this report, in order to eliminate the role of c-AMP in prostaglandin mediated cell cycle arrest, we use the-49 lymphoma variant (cyc^?) cells that lack adenylate cyclase activity. We demonstrate that dimethyl prostaglandin A₁ (dmPGA₁) inhibits DNA synthesis and cell growth in cyc^? cells. DNA synthesis is inhibited 42% by dmPGA₁ (50 μM) despite the fact that this cell line lacks cellular components needed for cAMP generation. The ability to decrease DNA synthesis depends upon the specific prostaglandin structure with the most effective form possessing the α,β unsaturated ketone ring. Dimethyl PGA₁ is most effective in inhibiting DNA synthesis in cyc^? cells, with prostaglandins PGE₁ and PGB₁ being less potent inhibitors of DNA synthesis. DmPGE₂ caused a significant stimulation of DNA synthesis. S-49 cyc^- variant cells exposed to (30–50 μm) dmPGA₁, arrested in the G₁ phase of the cell cycle within 24 h. This growth arrest was reversed when the prostaglandin was removed from the cultured cells; growth resumed within hours showing that this treatment is not toxic. The S-49 cyc^? cells were chosen not only for their lack of adenylate cyclase activity, but also because their cell cycle has been extensively studied and time requirements for G₁, S, G₂, and M phases are known. Within hours after prostaglandin removal the cells resume active DNA synthesis, and cell number doubles within 15 h suggesting rapid entry into S-phase DNA synthesis from the G₁ cell cycle block. The S-49 cyc^? cells are known to have a G₁/S boundary through M phase transition time of 14.8 h, making the location of the prostaglandin cell cycle arrest at or very near the G₁/S interface. The oncogenes, c-fos and c-myc which are normally expressed during G₁ in proliferating cells have a 2–3 fold enhanced expression in prostaglandin G₁ arrested cells. These data using the S-49 variants demonstrate that dmPGA₁ inhibits DNA synthesis and arrests the cell cycle independent of cAMP-mediated effects. The prostaglandin arrested cells maintain the gene expression of a G₁ synchronous cell which suggests a unique molecular mechanism for prostaglandin action in arresting cell growth. These properties indicate that this compound may be an effective tool to study molecular mechanisms of regulation of the cell cycle.     

Characterization of the cell cycle of cultured human diploid cells: Effects of aging and hydrocortisone

Age-related changes in the cytokinetics of human diploid cells in vitro have been compared in normal cultures and in cultures in which lifespan has been prolonged by the addition of hydrocortisone to the medium. For both cultures, with advancing age the fraction of cells in the actively proliferating pool decreased and the intercellular variation in cell cycle times increased. The average cell cycle time was prolonged during aging due almost entirely to changes in the duration of G₁. The duration of S remained constant, while a small delay in G₂ was observed in late passage cells near the end of their lifespan. Although the same pattern of change in proliferative parameters occurred in both control and hydrocortisone-treated cultures, the changes were somewhat delayed in the presence of the steroid. The results are interpreted in terms of several cell cycle models and suggest that the events controlling cell proliferation are sensitive to hydrocortisone modulation during the G₁ and possibly the G₂ periods.     

ANALYSIS OF INTESTINAL CELL PROLIFERATION AFTER GUANETHIDINE-INDUCED SYMPATHECTOMY

Neonatal administration of guanethidine-sulfate results in an alteration of the cell proliferative pattern of the small intestinal epithelium of the young adult rat. Sympathectomy with guanethidine has previously been shown to depress mitotic, labelling, and total cellular migration indices while increasing the generation cycle time (T_C) of small intestinal crypt cells as measured by a stathmokinetic method. The present study showed that the G₁, S and G₂ phases of the crypt cell cycle are altered by sympathectomy, G₁ accounting for most of the increase in T_C. In addition, the percentage of [³H]-thymidine labelled crypt cells is reduced and the duration of crypt cell transit is lengthened by guanethidine-induced sympathectomy.     

Intranucleolar visualization of nucleic acids and acidic proteins in inhibited and reactivated pea cotyledonary buds

Summary Nuclease-colloidal gold complexes and silver staining were used to visualize intranucleolar nucleic acids and argyrophilic proteins of the nucleolar organizers in bud cotyledonary cells ofPisum sativum. In the G_0–1 inhibited bud, a few RNA molecules were detected in the fibrillar component and in the unique fibrillar centre, close to the boundary with the fibrillar component of the nucleolus. DNA was present in the fibrillar component, in the fibrillar centre and in a few fibres crossing the perinucleolar halo. The acidic proteins were localized at the periphery of the fibrillar component but they were also present in the unique fibrillar centre. In the reactivated bud, RNA was particularly concentrated in the granular component and along fibres crossing the perinucleolar halo; a few RNA molecules were also detected at the boundary between the small fibrillar centres and the fibrillar component. DNA was localized in the same nucleolar component as in the inhibited bud, but it was distributed between several fibrillar centres. Acidic proteins coated these DNA loci. In the inhibited and reactivated bud connections between nucleolar DNA containing structures were displayed. The data are discussed in relation to the present knowledge of the functional architecture of the nucleolus.Abbreviations DNA deoxyribonucleic acid - DNase deoxyribonuclease - G_0–1 phase G₁ phase of the cell cycle indefinitely prolonged - PEG polyethylene glycol - RNA ribonucleic acid - RNase ribonuclease - S and G₂ phases synthetic and postsynthetic phases of the cell cycle - SPB saline phosphate buffer     

STUDIES ON THE DIVISION CYCLE OF MAMMALIAN CELLS : V. Modifications of Time Parameters by Different Steady-State Culture Conditions

In cultures of murine neoplastic mast cells, the duration of different phases of the division cycle (G₁, S, G₂, and mitosis [M]) was determined under optimal and several well-defined suboptimal growth conditions. Two methods of evaluation were applied to the same culture system: first, the relative number of G₁, S, G₂, and M cells was determined by pulse labeling of samples with thymidine-³H and subsequent radioautography in conjunction with a microfluorometric technique permitting rapid measurements of cellular DNA content; second, after pulse labeling with thymidine-³H, the variations with time of the mitotic labeling index were analyzed. Suboptimal culture conditions were obtained by reducing the concentration of single essential medium components (leucine, glucose, or serum) or by the addition of specific metabolic inhibitors (actinomycin D, amethopterin). Growth-limiting culture conditions resulted in increased generation times. Even under control conditions, the cell number doubling time exceeded the generation time, and this difference was more pronounced in suboptimal media. Under most of the suboptimal conditions tested, the increase in generation time was attributable primarily to an extended duration of the G₁ phase. Under certain growth-limiting conditions, however, other phases were also prolonged. In addition, the variabilities of the generation time and of certain cell cycle phases were increased under suboptimal culture conditions. Results obtained by the two methods of evaluation were, in general, in good agreement with each other. Some differences were, however, observed and interpreted in terms of cell death and/or asymmetric frequency distributions of cell cycle parameters.     

In vitro effects of ecdysterone on the spermatogonial cell cycle in Locusta

The effect of ecdysterone on specific phases of the cell cycle of Locusta migratoria migratorioides spermatogonia was assayed in vitro. An increase in labeling index was noted, indicating a decrease in duration of the G₁ phase. On addition of the hormone to adapted organs in vitro, spermatogonial mitotic index increases rapidly, then declines to a basal level within a time period which approximates that of the G₂ phase. Such a response indicates a removal of a G₂/M inhibition by the hormone.     

The role of the G1 period in the life cycle of eukaryotic cells

The objective of this study was to test the concept that the G₁ period lacks any specific function in the life cycle of mammalian cells and hence could be drastically reduced without any effect on the generation time. HeLa cells were grown in medium containing an optimum dose (60 μM) of hydroxyurea at which the duration of S period was prolonged with little or no increase in generation time. At this concentration of hydroxyurea, we observed a maximum of 3 h (or 28.5%) reduction in the G₁ period. We also studied the effects of synchronization in S phase by single and double thymidine blocks on cell size and its relationship to the duration of G₁ in the subsequent cycle. By these treatments, we could reduce the G₁ period by not more than 2 to 3 h. The reduction in G₁ period was not directly proportional to the size (volume) of the G₁ cells. These results suggest that G₁ period has certain specific functions and cannot be eliminated by alterations in culture conditions.     

A Stochastic Model For Cell Populations With Circadian Rhythms

A mathematical model for cell kinetics, based on a random walk, is developed. the model allows variations with time of the rates of passage of proliferating cells through the four phases of the mitotic cycle. Circadian variations in the mitotic and labelling indices of the Syrian hamster cheek pouch epithelium have previously been observed, and the random walk model has been used to simulate this phenomenon. Assuming that all basal cells are proliferative and that these cells leave the basal layer randomly throughout the mitotic cycle to become differentiated cells, it was found that the experimentally observed circadian rhythms of the mitotic and labelling indices could be reproduced in the model by postulating a circadian rhythm in the rate of passage of cells through the G₁ and S phases only. Moreover, the growth activity of cells in both the G₁ and S phases appears to reach a peak during the dark hours of the light-dark cycle, and to fall off rapidly in the early hours of daylight. the postulate of Møller, Larsen & Faber (1974) that injection of the animals with tritiated thymidine causes a shortening of the G₂ phase duration has been qualitatively confirmed by using the random walk model to simulate the FLM and MI curves after injection with tritiated thymidine.     

Conjugation Between G1 and G2 Phase Cells in Paramecium tetraurelia1

Cells of Paramecium tetraurelia, stock hr^d, cultured in a micro-capillary containing 1 μl fresh culture medium, expressed mating activity through the whole cell cycle. Mating-reactive G₂ phase cells can conjugate with cells of other phases. The G₂ phase cells, which have double (4C) the normal micronuclear DNA content, undergo pre-meiotic DNA synthesis when conjugated with G₁ phase cells. The micronucleus of the progeny from the cross between a G₁ and a G₂ cell becomes triploid.