Cultured Human Tumour Cells May Be Arrested In All Stages of the Cycle During Stationary Phase: Demonstration of Quiescent Cells In G1, S and G2 Phase

Six human colon carcinoma cell lines were induced to enter stationary phase of growth by nutrient deprivation and cell crowding. Growth kinetics parameters (cell number, flow cytometric analysis of DNA distribution, and labelling and mitotic indices) were measured sequentially for all lines during the various stages of in vitro growth. Our results demonstrated that a substantial fraction of cells (9–18%) were located in G₂, phase when they changed from an exponential to a stationary mode of growth. Moreover, a large number of cells in stationary phase of growth had an S-phase DNA content, as determined by flow cytometry, but failed to incorporate radioactive DNA precursors (up to 15-fold difference). to substantiate these findings. cells in stationary phase of growth were induced to enter exponential growth by re-seeding in fresh medium at a lower density. Subsequently observed changes in DNA-compartment distribution, and in labelling and mitotic indices were those expected from cells that had been arrested at different stages of the cycle during their previous stationary phase. Thus, the non-proliferating quiescent state (Q), traditionally located ‘somewhere’ in G₁, phase, appears to be composed also of cells that can be arrested at other stages of the cycle (Q_s, and Q_G). Although the proportion of such cells is rather small, their contribution to the growth kinetics behaviour of human in vivo tumours will become apparent following ‘recruiting’ or ‘synchronizing’ clinical manoeuvres and will prevent the formation of a clear-cut wave of synchronized cells.     

Daughter Cell Repair by Mammalian Cells in Culture after Potentially Lethal Radiation Damage

COLONY formation by irradiated surface-attached mammalian cells in culture requires that at least one of the progeny produced at the first post-irradiation division retains the capacity for unlimited division. Abortive colonies result when the irradiated parent cell has experienced sufficient damage to suppress eventual colony formation, but not to prevent the production of a small number of progeny. We now present data which indicate that, if given a suitable environment, progeny from cells “lethally” damaged by X-radiation (not capable of producing a macroscopic colony) can repair damage transferred (sectored) from the parent cell.     

Kinetic Analysis of Drug-Induced G2 Block In Vitro

The data on cell-cycle effects of two prospective antitumour agents, (+)-1,2,-bis(3,5-dioxopiperazine-l-yl)propane (soluble ICRF; NSC 169780) and 1,4-bis(2′chloroethyl)-1,4-diazabicyclo [2.2.1] heptane diperchlorate (CBH; NSC 57198) were used to determine whether a modified stathmokinetic experiment could predict the effects of continuous, long-term (0–48 hr) drug exposure in an in vitro L1210 murine leukaemia cell system. Generally, continuous drug exposure of exponentially growing cells does not provide sufficient quantitative information concerning cell-cycle-phase-specific mechanisms of drug action. Alternatively, stathmokinetic experiments, which are usually limited to some fraction of one cell doubling time, provide little information about long-term drug effects. By using mathematical models constructed for this purpose, however, stathmokinetic data can predict the overall proportion of cells affected by a drug though failing to discern between various kinds of drug action (e.g. reversible v. irreversible block, blocking v. killing action, etc.), especially when it occurs in G₂ phase. In addition, it can be shown that for at least one of the drugs (soluble ICRF) the stathmokinetic experiment fails to predict ‘after-effects’ of drug treatment which extend into the following cell cycle(s). It also becomes clear that the degradation of exponential growth characteristics of quickly dividing cells during long-term, continuous drug exposure makes prediction of cell-cycle kinetic perturbations uncertain when derived from short-duration stathmokinetic experiments. However, with care, the joint application of ‘short term’ (e.g. stathmokinesis) and ‘long term’ (e.g. continuous exposure) techniques allow adequate quantitative insight into drug-perturbed cell-cycle kinetics. the applicability of modelling techniques is discussed: in the present instance it is limited to lower drug concentrations. For higher drug concentrations, effects like increased ploidy, ineffective division, etc., make it impossible in the present study to obtain a clear picture of the kinetics.     

Epidermis Extracts (Chalone) Inhibit Cell Flux At the G1-S, S-G2 and G2-M Transitions In Mouse Epidermis

Epidermal cell flux at the G₁-S, S-G₂ and G₂-M transition was examined during the first 4 hr after injection of epidermis extract. the flux parameters were estimated by a combination of several methods. the G₁-S and S-G₂ transit rates were calculated on the basis of a double labelling technique with [³H]TdR, the G₂-M flux by means of colcemid and the relative proportion of cells in the S or G₂ phase by means of flow cytometry. All experiments were performed both in early morning and late evening, corresponding to maximum and minimum rates of epidermal cell proliferation in the hairless mouse. the epidermis extract inhibited the S-G and G₂-M transit rates to the same degree, while the inhibition of cell flux at the G₁-S transit was consistently stronger. In general, the inhibition of cell flux at the different transitions was most pronounced when the rate of cell proliferation was low and vice versa.     

The Sensitivity of G0-State Haemopoietic Spleen Colony-Forming Cells to A Stimulus For Proliferation

Haemopoietic spleen colony-forming units (CFU-s) close to the axis (axial CFU-s) of the long bones have a high probability of self-renewal. They are pluripotent cells and are largely in a G_o-State. By contrast, CFU-s close to the bone surface (marginal CFU-s) have a lower probability of self-renewal and are probably more mature, though still pluripotent. Most CFU-s proliferation arises in this zone. As a consequence, marginal CFU-s tend to have shorter G_o histories than do axial CFU-s. Femoral marrow was, therefore, divided into axial and marginal populations and the sensitivity of the CFU-s to an endogenous CFU-s-specific proliferation-stimulating factor was assessed and compared by the tritiated thymidine suicide technique. It was found that axial CFU-s are considerably more resistant to stimulation than are marginal CFU-s in that larger doses for longer periods of exposure are required to increase the proliferative activity of the cells. This behaviour is consistent with the suggestion that cells with a low division probability exist in deeper levels of the quiescent G_o-state. Although this hypothesis was developed from the behaviour of cells maintained in culture under sub-optimal physiological conditions, this phenomenon appears, in vivo, to be a characteristic of the stem cell population of haemopoietic tissue; their high resistance to stimulation maintaining the axial CFU-s in a quiescent state.     

Deficit in oxygen causes G2 budding and unbudded G2 arrest in Cryptococcus neoformans

Cryptococcus neoformans exhibited diphasic growth when grown under limited aeration. First, it grew exponentially, but at OD 1, the concentration of dissolved oxygen in culture decreased to 1 mg l(-1) and a second phase of slow growth was started. This phase was characterized by a shift of budding from S to G(2), a sharp decrease in budding index and a sharp increase in the proportion of unbudded G(2) cells to 80%. Thus, a deficit in oxygen was demonstrated to delay the timing of budding, prolong the G(2) phase and cause accumulation of cells after DNA synthesis, but before commitment to budding.     

Direct Measurement of the G1 Phase In Meristematic Cells At Two Different Temperatures

Abstract. The duration of the G₁ period in meristematic cells has been measured directly at two different temperatures by using a synchronous cell population 'labelled' as binucleate by treatment with caffeine. By studying the uptake of a radioactive DNA-precursor, it proved possible to determine the duration of the G₁ period in relation to the total interphase duration, at two temperatures tested, and to demonstrate that the relationship remained constant.     

G2 Sub-Population In Mouse Liver Induced Into Mitosis By Lead Acetate

A single intracardiac dose of lead acetate (40 μ lead/g body weight) induced a 25-fold increase in mitosis of mouse hepatocytes 5 hr after injection, as determined by autoradiography. the prompt appearance of a mitotic wave and the relatively large number of mitoses suggest that the mitotic cells were derived from a hepatocyte sub-population arrested in the G₂ phase. the injection of lead also stimulated a small increase in labeled hepatocytes within 6 hr. Analysis of grain counts gave no evidence for unscheduled DNA synthesis. the incremental labeled cells may have originated from a small fraction of the G₁ population that was ready to enter the S phase without the usual pre-synthetic delay.     

Nimotuzumab Enhances the Radiosensitivity of Cancer Cells In Vitro by Inhibiting Radiation-Induced DNA Damage Repair

Background

Nimotuzumab is a humanized IgG1 monoclonal antibody specifically targeting EGFR. In this study, we aimed to investigate the molecular mechanisms of nimotuzumab in its effects of enhancing cancer cell radiosensitivity.

Principal Finding

Lung cancer A549 cells and breast cancer MCF-7 cells were pretreated with or without nimotuzumab for 24 h before radiation to perform the clonogenic survival assay and to analyze the cell apoptosis by flow ctyometry. γ-H2AX foci were detected by confocal microscopy to assess the effect of nimotuzumab on radiation induced DNA repair. EGFR activation was examined and the levels of DNA damage repair related proteins in A549 cells at different time point and at varying doses exposure after nimotuzumab and radiation treatment were examined by Western blot. Pretreatment with nimotuzumab reduced clonogenic survival after radiation, inhibited radiation-induced EGFR activation and increased the radiation-induced apoptosis in both A549 cells and MCF-7 cells. The foci of γ-H2AX 24 h after radiation significantly increased in nimotuzumab pretreated cells with different doses. The phosphorylation of AKT and DNA-PKcs were remarkably inhibited in the combination group at each dose point as well as time point.

Conclusions

Our results revealed that the possible mechanism of nimotuzumab enhancing the cancer radiosensitivity is that nimotuzumab inhibited the radiation-induced activation of DNA-PKcs through blocking the PI3K/AKT pathway, which ultimately affected the DNA DSBs repair.     

Rat Serum Factors Inhibiting the G1-S Transition In Hepatocytes

An attempt was made to detect the serum factors inhibiting the G₁-S transition in synchronized, baby rat hepatocytes. In untreated adult rat serum, this inhibitory activity was always linked to high molecular weight (HMW) compounds. Incubation of serum with trypsin or chymotrypsin resulted in the formation of a low molecular weight (LMW) G₁-S inhibitory factor. the same result was obtained with fractions from adult rat liver but not with kidney or spleen fractions. Separation of the LMW factor by ultrafiltration increased its specific activity by about 10³. the active period in the cell cycle of both the LMW and HMW factors was the same: the late G₁ phase. However, the activity of the LMW factor was not blocked by the Kunitz factor. an enzymatic transformation of the HMW factor might be induced by liver cell membrane-bound proteases and constitute a mechanism regulating hepatocyte proliferation.     

HYDROXYUREA: USE IN DETERMINING THE DURATION OF G2 IN TETRAHYMENA

Observation of division of individual cells in microdrops, plus autoradiographic studies using tritiated thymidine and standard cell cycle analysis techniques, reveal that hydroxyurea (10 DIM) reversibly arrests the normal progression of exponentially growing Tetrahymena pyriformis through the initial 92 % of S-phase while not affecting cells in the terminal 8 % and in G₂ and division. Thus the fraction of the population of cells that is in G₂ can be approximately determined by the fraction of the population able to divide in the presence of hydroxyurea. This fraction can be related to the approximate duration of G₂ by calculations which compensate for the age gradient.     

Effects of Hydroxyurea On the Mitotic Activity and the G2 Phase In Hairless Mouse Epidermis

Hairless mice were given 5 mg hydroxyurea (HU) intraperitoneally (i.p.) followed by 0.15 mg Colcemid® at various times after HU. the animals were killed at 2 and 4 hr after Colcemid, the epidermal mitotic counts in dorsal skin were determined and the mitotic rates calculated. These were compared with the normal mitotic rates, and the ratios between the results from HU-treated and -untreated animals were calculated. Hydroxyurea caused a considerable reduction in the mitotic rate with a trough at 6 hr, followed by a wave of increased mitotic rate with a peak at 14 hr, followed by a secondary drop at 20 hr, and then a return to normal. Another group of mice were given HU only, and the fraction of epidermal cells in G₂ was measured by flow cytometry. From these animals, without previous injection of Colcemid, we also determined the mitotic counts and calculated the mitotic durations. Cells piled up in G₂ for the first 6 hr after HU injection, then the G₂ compartment was emptied. the results are discussed in relation to previous results from this department showing the effect of the same dose of HU on DNA synthesis in the same mouse strain. It is concluded that HU not only blocks or retards DNA synthesis in epidermal cells, but also affects the movement of cells through G₂ and M. the cell kinetic effects of HU thus seem to be very complex.     

Mammalian cells are not synchronized in G1-phase by starvation or inhibition: considerations of the fundamental concept of G1-phase synchronization

Synchronization of mammalian cells by starvation-refeeding or by inhibition-release are among the most commonly used techniques for division cycle analysis. An alternative analysis—in the form of a Gedanken or thought experiment—is presented, casting doubt on the utility of this synchronization method. Arresting cell growth produces a culture where all cells contain a G₁ amount of DNA. However, these cells are not arrested at a particular point in the G₁-phase. Analysis of 'G₁ arrested cells' suggests that, upon resumption of growth, the cells are not synchronized.     

The Relationship of G0 to the Cell Cycle of Haemopoietic Spleen Colony-Forming Cells

Normal haemopoietic stem cells, defined here as spleen colony-forming units (CFUs), are slowly proliferating and are generally considered to spend most of their time in the non-proliferative G₀-state. A series of experiments using various combinations of the stem cell proliferation inhibitor (NBME-IV) and stimulator (RBME-III) together with vinblastine as a mitotic blocking agent was designed to determine the location of the G₀-state relative to the cell cycle of the CFUs. From a knowledge of the effects of these agents, the expected results from three different G₀-cell cycle models were charted and compared with the observed proliferative behaviour of the CFUs following these treatments. It was concluded that the out-of-cycle G₀-state is located at the end of the G₁-phase of the cycle, so that on receiving a stimulatory signal, the CFUs can rapidly enter the DNA-synthesis phase.     

Expression of G1 and G2 cyclins measured in individual cells by multiparameter flow cytometry: a new tool in the analysis of the cell cycle

Abstract. Multivariate analysis of the expression of cyclin proteins and DNA content has opened new possibilities for the study of the cell cycle. By virtue of their cell cycle phase specificity, the expression of cyclins may serve, in addition to DNA content, as another marker of a cell's position in the cycle, and provide information about the proliferative potential of cell populations. Several applications of the methodology based on bivariate analysis of DNA content v . expression of B, E and D type cyclins are reviewed: 1 expression of cyclins by individual cells during their progression through the cycle can be studied, using exponentially growing cells without the necessity of cell synchronization or other perturbations of the cycle; 2 cells having the same DNA content but residing in different phases of the cycle (e.g. G₂ diploid v. G₁ tetraploid) can be distinguished; 3 cell transition from G₀ to G₁ and progression through G₁ (e.g. mitogen stimulated lymphocytes) can be assayed; 4 the population of proliferating cells can be distinguished from noncycling cells based on dual cell labelling with a G₁ and G₂ cyclin antibody; 5 cyclin restriction points can serve as additional cell cycle landmarks to map the point of action of antitumour drugs; 6 unscheduled expression of cyclins (e.g. the presence of cyclin B1 during G₁ and S) can be detected in several tumour transformed cell lines, possibly indicating disregulation of the machmery of cell cycle progression. The last finding 6 is of special importance, because such disregulation may be of prognostic consequence in human tumours.     

ON THE EXISTENCE OF 'ARRESTED G2 CELLS' IN MOUSE EPIDERMIS

It has been postulated that mouse epidermis contains two populations of resting cells, one of which is blocked at the G₁-S boundary and the other between G₂ and mitosis. the ‘arrested G₂ cells’ were estimated, by the labelled mitosis method, to comprise 510% of the epidermal population and presumed to function as a ‘reserve pool’ which could be activated by wounding. A comprehensive search has now been carried out for arrested G₂ cells in mouse epidermis using the direct methods of single cell and flow through cytophotometry. No evidence was obtained which supports the existence of such a cell compartment. Suitable control experiments were carried out to ensure that G₂ cells were not lost during the isolation of epidermal nuclei.     

Monocytic differentiation of HL60 cells induced by potent analogs of vitamin D3 precedes the G1/G0 phase cell cycle block

Abstract. Differentiation of mammalian cells is accompanied by reduced rates of proliferation and an exit from the cell cycle. Human leukemic cells HL60 present a widely used model of neoplastic cell differentiation, and acquire the monocytic phenotype when exposed to analogs of vitamin D₃ (VD₃). The maturation process is accompanied by two blocks in the cell cycle: an arrest in the G₁/G₀ phase, and a recently described G₂+ M block. In this study we have analyzed the traverse of the cell cycle phases of the well-differentiating HL60-G cells exposed to one of ten analogs of VD₃, and compared the cell cycle effects of each compound with its potency as a differentiation-inducing agent. We found that in general there was a good correlation between the effects of these compounds on the cell cycle and on differentiation, but the best cell cycle predictor of differentiation potency was the extent of accumulation of the cells in the G₂ compartment. All analogs induced a marked decrease in the mitotic index, and polynucleation of HL60 cells was produced, especially by compounds which were effective as inducers of differentiation. Time course studies showed that induction of differentiation was accompanied by a transient increase of the proportion of cells in the G₂+ M compartment, but preceded the G₁ to S, and the G₂ compartment blocks. These studies indicate that complex changes in the cell cycle traverse accompany, but do not precede, the acquisition of the monocytic phenotype by HL60 cells.     

SEPARATION OF PROLIFERATING CFU FROM G2 CELLS OF MURINE BONE MARROW

The technique of velocity sedimentation was employed to fractionate mouse bone marrow CFU-s relative to two different phases of the cell cycle. CFU-s in DNA synthesis which are destroyed by hydroxyurea were separated from other smaller CFU-s which were shown to be insensitive to the drug and are presumably those CFU-s in the G₂ phase of cell cycle.