The effect of cell-to-cell contact on the surface morphology of Chinese hamster ovary cells

In the previous report (Porter et al., in this issue) morphological changes in Chinese hamster ovary (CHO) cells during the cell cycle were described. In this report we describe the role of intercellular contact on these changes. We find that intercellular contact is required for cells to exhibit the morphologies Porter et al. described for S and G₂. When cells are synchronized by mitotic selection and plated onto cover slips at very low density such that no intercellular contact occurs, the cells remain in a G₁ configuration (rounded and highly blebbed through G₁, S, and G₂). This G₁ morphology is also observed in nonsynchronized log phase cells plated at low densities and allowed to grow for several generations. The addition of conditioned medium from confluent cultures does not induce low density cells to change morphology during the cell cycle. These results indicate that extensive intercellular contact is required for the complete expression of the morphological changes associated with the cell cycle (as described by Porter et al.). It is concluded that although classic contact inhibition of movement and of growth may be absent in this transformed cell line, some contact-dependent response persists.     

MITOSIS AND THE PROCESSES OF DIFFERENTIATION OF MYOGENIC CELLS IN VITRO

The relation between the mitotic cycle and myoblast fusion has been studied in chick skeletal muscle in vitro. The duration of the cell cycle phases was the same in both early and late cultures. By tracing a cohort of pulse-labeled cells, it was found that myoblast fusion does not occur in S, G₂, or M. Cell surface alterations required for fusion are dependent upon the position of the cell in the division cycle. In early cultures, fusion takes place only after a minimum delay of 5 hr from the time the cell has entered G₁. The mitosis preceding fusion may condition the cell for the abrupt shift in synthetic activity that occurs in the subsequent G₁. In older cultures fusion of labeled cells is diminished. Two factors account for the cessation of fusion in older cultures. First, the number of myogenic stem cells declines, but these cells do not disappear as the cultures mature. Their persistence was demonstrated by labeling dividing mononucleated cells in older cultures and challenging them with nascent myotubes. Some of these labeled cells were incorporated into the forming myotubes. Second, a block to fusion develops during myotube maturation. Well developed myotubes challenged with labeled competent myogenic cells failed to incorporate the labeled nuclei.     

CHANGES IN GLUCOSE OXIDATION DURING GROWTH OF EMBRYONIC HEART CELLS IN CULTURE

A rapid and convenient method has been utilized to investigate glucose oxidation during growth of chick embryo heart cells in tissue culture. Primary isolates of chick embryo heart cells showed exponential growth when plated at low densities and exhibited density-inhibited growth as cultures became confluent. The density-dependent growth inhibition of chick embryo heart cells is associated with a marked decrease in the specific activity of glucose oxidation to CO₂. This decrease in glucose oxidation was observed as density increased as either a function of time in culture or as related to initial plating density. The decrease in ¹⁴CO₂ production associated with density-dependent inhibition of growth is due to a marked decrease in activity of the pentose phosphate pathway.     

A KINETIC ANALYSIS OF MYOGENESIS IN VITRO

Conditions which yielded reproducible growth kinetics with extensive, relatively synchronous differentiation are described for chick muscle cultures. The effects of cell density and medium changes on the timing of cell fusion were examined. Low-density cultures which received a change of medium at 24 hr after plating show the highest rate of cell fusion, increasing from 15 to 80% fused cells in a 10 hr period. These optimal culture conditions were employed to reexamine two questions from the earlier literature on muscle culture: (a) can cells which normally would fuse at the end of one cell cycle be forced to go through another cell cycle before fusion; and (b) how soon after its final S period can a cell complete fusion? In answer to the first question, it was found that if the medium is changed, many cells which would otherwise fuse can be made to undergo another cell cycle before fusion. In the second case, radioautographs were made from cultures incubated with tritiated thymidine for various times at the beginning of the fusion period. These show labeled nuclei in myotubes as early as 3 hr after the beginning of the incubation period. This indicates that cells can fuse as early as the beginning of the G₁ period, and suggests that there is not an obligatory exit from the cell cycle or a prolonged G₁ period before cell fusion and differentiation during myogenesis.     

The effect of potassium on the cell membrane potential and the passage of synchronized cells through the cell cycle

The cell membrane potential of cultured Chinese hamster cells is known to increase at the start of the S phase. The putative role of the cell membrane potential as a regulator of cell proliferation was examined by following the cell cycle traverse of synchronized Chinese hamster cells in the presence or absense of high exogenous levels of potassium. An increase in external potassium levels results in a depressed membrane potential and a reduced rate of cell proliferation. A potassium concentration of 115 mM was used in experiments with synchronized cells since at that level cell proliferation is almost completely halted, recovery of growth is rapid and complete, and the membrane potential is reduced to a level well below that normally found in cells in the G₁ phase. A mitotic population was divided into four aliquots and plated in either control medium or medium containing 115 mM K⁺. Cells placed directly into high K⁺ medium were retarded in their exit from mitosis and displayed a delayed and abnormal entry into the S phase. If control medium was added after two hours, cell cycle traverse was normal, but delayed by two hours compared to control cells. If the mitotic cells were plated directly into control medium and two hours later were shifted to high K⁺ medium, the cells entered the S phase in the absence of the normally observed increase in membrane potential and proceeded to the next mitosis normally. It was concluded that the increase in membrane potential observed at the start of the S phase in isolated synchronized cells is not a requirement for the initiation of DNA synthesis. In addition, sensitivity to the high potassium regimen was found at two different times during the cell cycle. In one case, cells were impeded in their transit through mitosis. Such cells displayed an altered chromosome structure which may account for the partial mitotic block. In the second case, synchronized cells displayed a sensitivity to the high potassium regimen in early G₁ which appeared to be separate from the block in mitosis and independent of a change in the membrane potential.     

Control of mouse myoblast commitment to terminal differentiation by mitogens

Regulation of the transition of mouse myoblasts from proliferation to terminal differentiation was studied with clonal density cultures of a permanent clonal myoblast cell line. In medium lacking mitogenic activity, mouse myoblasts withdraw from the cell cycle, elaborate muscle-specific gene products, and fuse to form multinucleated myotubes. Addition of a purified mitogen, fibroblast growth factor, to mitogen-depleted medium stimulates continued proliferation and prevents terminal differentiation. When mitogens are removed for increasing durations and then refed, mouse myoblasts irreversibly commit to terminal differentiation: after 2–4 h in the absence of mitogens, myoblasts withdraw from the cell cycle, elaborate muscle-specific gene products, and fuse in the presence of mitogens that have been fed back. Population kinetics of commitment determined with ³H-thymidine labeling and autoradiography suggest the following cell-cycle model for mouse myoblast commitment: (1) if mitogens are present in the extracellular environment of myoblasts in G₁ of the cell cycle, the cells enter S and continue through another cell cycle; (2) if mitogens have been absent for 2 or more hours, cells in G₁ do not enter S; the cells commit to differentiate, permanently withdraw from the cell cycle (will not enter S if mitogens are refed), and they subsequently elaborate acetylcholine receptors and fuse (even if mitogens are refed); (3) cells in other phases of the cell cycle continue to transit the cell cycle in the absence of mitogens until reaching the next G₁. The commitment kinetics and experiments with mitotically synchronized cells suggest that the commitment “decision” is made during G₁. Present results do not, however, exclude commitment of some cells in other phases of the cell cycle.     

Analysis of radiation‐induced changes to human melanoma cultures using a mathematical model

Objectives: Tumour cells respond to ionizing radiation by cycle arrest, cell death or repair and possible regrowth. We have developed a dynamic mathematical model of the cell cycle to incorporate transition probabilities for entry into DNA replication and mitosis. In this study, we used the model to analyse effects of radiation on cultures of five human melanoma cell lines. Materials and methods: Cell lines were irradiated (9 Gy) prior to further culture and harvesting at multiple points up to 96 h later. Cells were fixed, stained with propidium iodide and analysed for G₁‐, S‐ and G₂/M‐phase cells by flow cytometry. Data for all time points were fitted to a mathematical model. To provide unique solutions, cultures were grown in the presence and absence of the mitotic poison paclitaxel, added to prevent cell division. Results: The model demonstrated that irradiation at 9 Gy induced G₂‐phase arrest in all lines for at least 96 h. Two cell lines with wild‐type p53 status additionally exhibited G₁‐phase arrest with recovery over 15 h, as well as evidence of cell loss. Resumption of cycling of surviving cells, as indicated by increases in G₁/S and G₂/M‐phase transitions, was broadly comparable with results of clonogenic assays. Conclusions: The results, combined with existing data from clonogenic survival assays, support the hypothesis that a dominant effect of radiation in these melanoma lines is the induction of long‐term cell cycle arrest.     

Ultrastructural localization of adenosine triphosphatase activity in HeLa cells at various stages of the cell cycle

Summary HeLa cells in a monolayer culture were synchronized to S, G₂ and mitotic phases by use of excess (2.5 mM) deoxythymidine double-block technique. The localizations of Ca⁺⁺-activated adenosine triphosphatase (ATPase) at different phases of the cell cycle were studied using light and electron-microscopic histochemical techniques, and microphotometric comparisons of the densities of reaction products. Enzyme reaction product was always localized in the endoplasmic reticulum, nuclear membrane, mitochondria and Golgi apparatus, but there were qualitative and quantitative differences related to the phases of the cell cycle. In S phase the activity was mainly concentrated in a perinuclear area of the cytoplasm whereas in G₂ and mitosis the activity was scattered throughout the cell. The total activity per cell was maximal in G₂, was less in S phase and least in mitosis. Activity in the mitochondria and endoplasmic reticulum was distinctly less in mitosis than in other phases of the cell cycle. The mitochondrial ATPase differed from the ATPase at other sites in ion dependence and sensitivity to oligomycin. The results suggest that there may be several distinct ATPases in proliferating cells.     

DNA synthesis and the cell cycle in cultures of normal and mutant (mdg/mdg) embryonic mouse muscle cells.

The relationship between cell fusion, DNA synthesis and the cell cycle in cultured embryonic normal and dysgenic ($\text{mdg}\text{mdg}$) mouse muscle cells has been determined by autoradiography. The experimental evidence shows that the homozygous mutant myotubes form by a process of cell fusion and that nuclei within the myotubes do not synthesize DNA or undergo mitotic or amitotic division. The duration of the total cell cycle and its component phases was statistically the same in 2-day normal and mutant ($\text{mdg}\text{mdg}$) myogenic cultures with the approximate values: T, 21.5 hr; G₁, 10.5 hr; S, 7.5 hr; and G₂, 2.5 hr. In both kinds of cultures, labeled nuclei appeared in myotubes 15–16 hr after mononucleated cells were exposed to [³H]thymidine, and the rate of incorporation of labeled nuclei into multinucleated muscle cells was comparable in control and dysgenic cultures. Thus, homozygous $\text{mdg}\text{mdg}$ muscle cells in culture are similar to control cells with respect to their mechanism of myotube formation and the coordinate regulation of DNA synthesis and the cell cycle during myogenesis.     

An effect of cell-cycle position on ultraviolet-light-induced mutagenesis in Chinese hamster ovary cells

Using synchronous populations obtained by selectively detaching mitotic cells from cultures grown in monolayer, we demonstrate here that Chinese hamster ovary (CHO) cells exhibit a differential sensitivity to mutation induction by UV as a function of position in the cell cycle. When mutation induction to 6-thioguanine (TG) resistance is monitored, several maxima and minima are displayed during cell-cycle traverse, with a major maximum occurring in early S phase. Although cells in S phase are more sensitive to UV-mediated cell lethality than those in G₁ or G₂/M phases, there is not a strict correlation with induced mutation frequency. Fluence-response curves obtained at several times during the cell cycle yield D_q values approximating 6 J/m². The primary survival characteristic which varies with cell cycle position is D₀, ranging from 2.5 J/m² at 6 h after mitotic selection to 5.5 J/m² at 11 h afterward. Based on studies with asynchronous, logarithmically growing populations, as well as those mitotically selected to be synchronous, the optimum phenotypic expression time for induced TG resistance is 7–9 days and is essentially independent of both UV fluence and position in the cell cycle. All isolated mutants have altered hypozanthine—guanine phosphoribosyl transferase (HGPRT) activity, and no difference in the residual level of activity was detected among isolated clones receiving UV radiation during G₁, S, or late S/G₂ phases of the cell cycle. Changes in cellular morphology during cell-cycle traverse do not contribute to the differential susceptibility to UV-induced mutagenesis.     

Osteogenesis in cultures of limb mesenchymal cells

The results of previous reports demonstrated that osteoblasts develop in cultures derived from phenotypically unexpressive stage 24 chick limb mesenchymal cells. The observations reported here suggest that initial cell plating densities may provide environmental conditions deterministic to a particular limb phenotype. Quantitative microscopic studies, histochemical localization of calcium phosphate, and electron microscopy indicate that osteoblasts develop in cultures derived from stage 24 limb mesenchymal cells. Additionally, 1–3% of the cells from stage 24 limbs are associated with mineral deposits when plated at initial high densities (5 × 10⁶ cells per 35-mm culture dish), while more than 50% of the cells are associated with cartilage by Day 9. Cultures plated at intermediate seeding densities (between 2.0 and 2.5 × 10⁶ cells per 35-mm culture dish) have minimal cartilage development, and approximately 20% of the cells are associated with mineral by Day 9. Furthermore, cultures prepared from stage 31 limb mesenchymal cells form well-developed bone nodules with both osteoblasts and osteocytes present, but no cartilage. It is clear from these observations and from a consideration of the initiation of osteogenesisin vivo that the initiation of bone development in the limb is not associated with cartilage development. Based on these studies and observations on the effect of nutrient factors on phenotypic expression in culture, an hypothesis is presented relating differential vascularization and nutrient flow to the determination of limb phenotypesin vivo.     

Exogenous retinoic acid decreases in vivo and in vitro proliferative activity during the early migratory stage of neural crest cells

We have previously demonstrated that directional migration of neural crest cells (NCC) is associated with a high cell density, resulting from an active cell proliferation. It is also known that treatment with retinoic acid (RA) causes a dose-dependent inhibition of proliferation of some cell types, and that administration of RA during the early stages of embryonic development, induces cranio-facial abnormal patterns corresponding to NCC derivatives. In view of these findings, it was of interest to determine if exogenous RA is a potential modulator of the mitotic rate of NCC, and to explore the hypothesis of an inhibitory effect exerted by RA on the proliferative behaviour of NCC in vivo and in vitro. Homogenates of RA-treated chick embryos showed a low [³H]dT incorporation, indicating a generalized diminution of DNA synthesis. The labelling index (LI=number of labelled cells/total number of cells) revealed that NCC from RA-treated and control embryos had higher values of [³H]dT incorporation than neural tube cells (P < 0.0001). Autoradiographs of RA-treated chick embryos showed a significantly lower [³H]dT incorporation in NCC at the prosencephalic and mesencephalic levels, as well as in the neural tube cells at the prosencephalic, mesencephalic and rhombencephalic levels, than in control chick embryos (P < 0.0001). NCC cultures treated with 1 or 10 μm RA had a significantly lower LI than in cultures treated with 0.1 μm RA or control cultures (P < 0.04). In chick embryos, the mitotic index of NCC was 0.026 for RA-treated and 0.033 for controls, while the duration of the cell cycle was significantly longer in the NCC of RA-treated embryos (～ 40 h) than in controls (～ 25 h). The length of the cell cycle phases of NCC was similar in both experimental conditions, except for G₁ phase, which was significantly longer in the RA-treated group than in controls. These results show that RA blocks DNA synthesis and lengthens the proliferative behaviour of NCC both in early chick embryos and in vitro, effects that could modify the morphogenetic patterns of NCC distribution through a decreased cell population.     

Molecular mechanisms of the chromosome condensation and decondensation cycle in mammalian cells

The chromosomes undergo a condensation-decondensation cycle within the life cycle of mammalian cells. Chromosome condensation is a complex and critical event that is necessary for the equal distribution of genetic material between the two daughter cells. Although chromosome condensation-decondensation and segregation is mechanistically complex, it proceeds with high fidelity during the eukaryotic cell division cycle. Cell fusion studies have indicated the presence of chromosome condensation factors in mammalian cells during mitosis. If extracts from mitotic cells are injected into immature oocytes of Xenopus laevis, they induce meiotic maturation (i.e. germinal vesicle breakdown and chromosome condensation) within 2–3 hours. Recently, we showed that the maturation-promoting activity of the mitotic cell extracts is inactivated by certain protein factors present in cells during the G₁ period. The activity of the G₁ factors coincides with the process of chromosome decondensation that begins at telophase and continues throughout the G₁ period. These studies have revealed that the mitotic factors and the G₁ factors play a pivotal role in the regulation of condensation and decondensation of chromosomes. Furthermore, our studies strongly suggest that nonhistone protein phosphorylation and dephosphorylation may mediate chromosome condensation and decondensation, respectively.     

Hyaluronic acid bonded to cell-culture surfaces stimulates chondrogenesis in stage 24 limb mesenchyme cell cultures

The influence on the differentiation of stage 24 chick limb mesenchymal cells of hyaluronic acid (HA) covalently bonded onto plastic substrates has been examined. Under control conditions, stage 24 cells express phenotypes related to the initial plating density: When plated at high density (5 X 10(6) cells/35-mm culture dish), these cells express a chondrogenic phenotype collectively visualized as a mound or nodule of cartilage. Cartilage nodules are not found in cultures plated at intermediate or low densities, 2 X 10(6) and 1 X 10(6) cells/35-mm dish, respectively. However, when cells are plated onto HA surfaces, expression of the cartilage phenotype occurs at all three plating densities in roughly comparable frequencies. This increase in cartilage nodule formation does not appear to be due to an increased plating efficiency or increased replication rate. The observed effect is dependent on HA concentration; with an increase in bound HA, an increase in the number of cartilage nodules is observed. Digestion of HA substrates with hyaluronidase abolishes the stimulation in chondrogenesis, while no effect is observed if the HA substrates are treated with either trypsin or alkaline borohydride. No other glycosaminoglycan, except for the HA analog, unsulfated chondroitin, exhibits this unique stimulation of chondrogenic expression. While the rate of radiolabeled sulfate incorporation is dramatically increased with cells plated onto HA substrates, the protein biosynthetic rate, as evidenced by radiolabeled proline incorporation, remains unaffected. This dramatic increase in chondrogenic expression is considered in contrast to the previously reported inhibitory effect of HA substrates on myogenesis. These observations suggest that HA may have a regulatory role in the chondrogenic differentiation of chick limb mesenchymal cells.     

Production of plasminogen activator by synchronized normal and rous sarcoma virus-transformed chicken fibroblasts in culture

We studied intracellular activity of the plasminogen activator within the cell cycle of chemically synchronized normal and RSV-transformed chick fibrolasts in culture. Consideration has also been given to the relationship between the plasminogen activator activity and cycles of DNA synthesis or mitosis in cycling fibroblasts after viral infection. The plasminogen activator activity of the cell lysates was assayed on [¹²⁵I]fibrin-coated Petri dishes and was expressed as the radioactivity released from the plates. Normal fibroblasts produced detectable levels of plasminogen activator in the S-phase and late G₂-phase or mitosis of the cell cycle. In contrast, RSV-transformed cells produced high levels of this activator throughout the entire cell cycle although this activity fluctuated and reached a maximum in the G₂-M periods. We also found that the level of plasminogen activator activity in the transformed fibroblasts is influenced by the cycles of DNA synthesis and that cell division is required for the appearance of plasminogen activator activity in the ‘de novo’ virus-infected cultures.     

CELL CYCLE TIME DETERMINATIONS BASED ON LIQUID SCINTILLATION COUNTING OF 3H-TdR LABELED MITOTIC CELLS

Following a 10 min pulse labeling with ³H-TdR, flasks of asynchronous monolayer cultures of Chinese hamster ovary cells were subjected to mitotic selection at 2 hr intervals. The mitotic index of the selected populations was always greater than 90%. Counts per min per cell obtained by liquid scintillation counting were plotted versus time after the pulse label. Comparisons were made between cycle times obtained by the mitotic-scintillation counting method and by the standard per cent labeled mitosis technique. The resulting curves were used for calculations of the cell cycle times and the lengths of G₁, S, G₂ and M phases of the cell cycle. There was less than 2% difference in the cell cycle times obtained using the scintillation method as compared to times calculated from autoradiographic data obtained from individual petri dishes. The mitotic-scintillation counting technique is simple, accurate and rapid and allows the calculation of the cell kinetics parameters within 1 hr of the end of the experiment.     

High plating efficiency with plant cell cultures

In this paper we describe a simple method to improve the plating efficiency in plant cell cultures.Two-stage plating is used; in the first stage the cells are inoculated at high density in 0.2% agarized culture medium for ten days to facilitate growth; under this condition, each cell produces a single micro-colony trapped in the agar network. In the second stage the colonies are plated at different densities in 1% agarized medium.These colonies are self-sufficient and able to improve the cell growth by conditioning the medium.Abbreviations 6-BAP 6-Benzyl-aminopurine - 2,4-D 2,4-Dichlorophenoxyacetic acid     

Mechanism of soybean trypsin inhibitor induced polyspermy as determined by an analysis of refertilized sea urchin (Arbacia punctulata) eggs

The decreased growth rate observed in older muscle cultures has been attributed to the withdrawal of cells from the proliferative pool by fusion. The possibility was examined that this decrease reflects changes in the cell cycle as well. Before fusion, the cycle is relatively short and uniform (10.0 ± 2.7 hr) becoming greatly extended and more variable (19.2 ± 8.5 hr) in cultures undergoing fusion. Most of the increase in generation time is introduced by a long, variable G₁ phase, that phase to which fusion is restricted. These stage-specific cycle characterstics are a function of changes occurring in the medium, rather than of time in culture. Older cultures, refed fresh medium acquire the cell cycle characteristics of younger cultures, and conversely, early cultures fed medium collected from older cultures exhibit cycle measurements typical of older cultures.Although the mean G₁ time almost doubles at the time of fusion, there is no evidence that cells actually withdraw from the cycle prior to fusion. Continuous labeling before and after the initiation of fusion indicate that at all stages virtually 100% of the mononucleated cells incorporate ³H-TdR. Since fusion occurs in G₁, it seems reasonable to assume that some preparation for fusion occurs during this phase and the probability of fusion increases with protraction of G₁.     

Cutting edge: Chk1 directs senescence and mitotic catastrophe in recovery from G2 checkpoint arrest

Besides the well‐understood DNA damage response via establishment of G₂ checkpoint arrest, novel studies focus on the recovery from arrest by checkpoint override to monitor cell cycle re‐entry. The aim of this study was to investigate the role of Chk1 in the recovery from G₂ checkpoint arrest in HCT116 (human colorectal cancer) wt, p53^–/– and p21^–/– cell lines following H₂O₂ treatment. Firstly, DNA damage caused G₂ checkpoint activation via Chk1. Secondly, overriding G₂ checkpoint led to (i) mitotic slippage, cell cycle re‐entry in G₁ and subsequent G₁ arrest associated with senescence or (ii) premature mitotic entry in the absence of p53/p21^WAF1 causing mitotic catastrophe. We revealed subtle differences in the initial Chk1‐involved G₂ arrest with respect to p53/p21^WAF1: absence of either protein led to late G₂ arrest instead of the classic G₂ arrest during checkpoint initiation, and this impacted the release back into the cell cycle. Thus, G₂ arrest correlated with downstream senescence, but late G₂ arrest led to mitotic catastrophe, although both cell cycle re‐entries were linked to upstream Chk1 signalling. Chk1 knockdown deciphered that Chk1 defines long‐term DNA damage responses causing cell cycle re‐entry. We propose that recovery from oxidative DNA damage‐induced G₂ arrest requires Chk1. It works as cutting edge and navigates cells to senescence or mitotic catastrophe. The decision, however, seems to depend on p53/p21^WAF1. The general relevance of Chk1 as an important determinant of recovery from G₂ checkpoint arrest was verified in HT29 colorectal cancer cells.