Rapid analysis of drug effects on the cell cycle

The Mitotic and Metabolic Effects of Phosphatidic Acid in the Primary Muscle Cells of Turbot (Scophthalmus maximus)

Searching for nutraceuticals and understanding the underlying mechanism that promote fish growth is at high demand for aquaculture industry. In this study, the modulatory effects of soy phosphatidic acids (PA) on cell proliferation, nutrient sensing, and metabolic pathways were systematically examined in primary muscle cells of turbot (Scophthalmus maximus). PA was found to stimulate cell proliferation and promote G1/S phase transition through activation of target of rapamycin signaling pathway. The expression of myogenic regulatory factors, including myoD and follistatin, was upregulated, while that of myogenin and myostatin was downregulated by PA. Furthermore, PA increased intracellular free amino acid levels and enhanced protein synthesis, lipogenesis, and glycolysis, while suppressed amino acid degradation and lipolysis. PA also was found to increased cellular energy production through stimulated tricarboxylic acid cycle and oxidative phosphorylation. Our results identified PA as a potential nutraceutical that stimulates muscle cell proliferation and anabolism in fish.

RNA interference–mediated cyclooxygenase-2 inhibition prevents prostate cancer cell growth and induces differentiation: modulation of neuronal protein synaptophysin, cyclin D1, and androgen receptor

Cyclooxygenase-2 (COX-2) plays an important role in tumor development and progression. Inconsistent reports on the expression of COX-2 in early versus advanced prostate cancer raised the question on whether COX-2 inhibition affects prostate carcinogenesis. Evidence from recent studies indicates that prostate carcinogenesis depends on the altered expression of several factors including androgen receptor signaling, proinflammatory, and cell cycle regulatory genes. Very often, the outcome of androgen ablation treatment is not effective and, eventually, the cancer becomes androgen independent followed by activation of several survival genes and transcription factors. Most importantly, the extent of the influence of COX-2 on the regulation of the androgen receptor, cyclin D1, and other factors involved in cancer growth is not known. Using RNA interference-mediated COX-2 inhibition in metastatic prostate cancer cells, this study has shown that the silencing of COX-2 at the mRNA level can induce cell growth arrest and down-regulate androgen receptor and cyclin D1. We have further shown for the first time that COX-2 knockdown prostate cancer cells depict morphologic changes associated with enhanced expression of differentiation markers, particularly the neuronal protein synaptophysin along with activation of p21((Waf1/Cip1)) and p27((Kip1)). In summary, our findings determined the role of COX-2 in prostate carcinogenesis and its control on COX-2-independent targets. Second, abrogation of COX-2 and activation of synaptophysin provide evidence for the control of COX-2 on the expression of a neuronal protein. Finally, our findings provide evidence of COX-2-independent targets promoting cell growth arrest and differentiation in cells lacking COX-2 expression at the mRNA level.

Significant overexpression of metallothionein and cyclin D1 and apoptosis in the early process of rat urinary bladder carcinogenesis induced by treatment with N-butyl-N-(4-hydroxybutyl)nitrosamine or sodium L-ascorbate

Effects of a genotoxic bladder carcinogen, N-butyl-N-(4-hydroxybutyl)nitrosamine (BBN) and a non-genotoxic bladder promoter, sodium L-ascorbate (Na-AsA), on protein expression, cell proliferation and apoptosis of the bladder epithelium with or without the influence of testicular castration were investigated. Male F344 rats were divided into six groups (groups 1-6). BBN was given with 0.05% drinking water to groups 1 and 4 for 8 weeks, groups 2 and 5 received diet with 5% Na-AsA. Then the animals were treated without any chemicals. Groups 3 and 6 were non-treated controls. Testicular castration was carried out 2 weeks before commencement of chemical treatment on groups 4-6. The total observation period was 18 weeks. Overexpression of cyclin D1 was induced by BBN but not Na-AsA and the degree of overexpression was higher in the order simple hyperplasia, papillary or nodular hyperplasia, papilloma and carcinoma. Metallothionein (MT) was also overexpressed in bladder epithelium treated with BBN but not Na-AsA, but was decreased in papillomas and never found in a carcinoma. Cyclin D1-positive cells were essentially MT-negative. Therefore, it is speculated that MT protects genes from insult by genotoxic carcinogens and its lack is associated with tumor development. Apoptotic cell death occurred during treatment with BBN and Na-AsA and after their withdrawal. Chromatin condensation of many G0/G(1) cells was particularly marked on flow cytometry analysis 1 week after cessation of treatment, this being considered as an early apoptotic change. Although testicular castration had no influence on the above events, it resulted in decreased tumor formation as compared with the case of similarly treated intact animals. Our data demonstrate that overexpression of MT and cyclin D1 is specific for treatment with a genotoxic carcinogen, and suggest that MT overexpression may play an important suppressive role in the early stages of rat urinary bladder carcinogenesis.

EGF-Receptor phosphorylation and signaling are targeted by H2O2 redox stress

Inflammation of the respiratory tract is associated with the production of reactive oxygen species, such as hydrogen peroxide (H2O2) and superoxide (O2-), which contribute extensively to lung injury in diseases of the respiratory tract. The mechanisms and target molecules of these oxidants are mainly unknown but may involve modifications of growth-factor receptors. We have shown that H2O2 induces epidermal growth factor (EGF)-receptor tyrosine phosphorylation in intact cells as well as in membranes of A549 lung epithelial cells. On the whole, total phosphorylation of the EGF receptor induced by H2O2 was lower than that induced by the ligand EGF. Phosphorylation was confined to tyrosine residues and was inhibited by addition of genistein, indicating that it was due to the activation of protein tyrosine kinase (PTK). Phosphoamino acid analysis revealed that although the ligand, EGF, enhanced the phosphorylation of serine, threonine, and tyrosine residues, H2O2 preferentially enhanced tyrosine phosphorylation of the EGF receptor. Serine and threonine phosphorylation did not occur, and the turnover rate of the EGF receptor was slower after H2O2 exposure. Selective H2O2-mediated phosphorylation of tyrosine residues on the EGF receptor was sufficient to activate phosphorylation of an SH2-group-bearing substrate, phospholipase C-gamma (PLC-gamma), but did not increase mitogen-activated protein (MAP) kinase activity. Moreover, H2O2 exposure decreased protein kinase C (PKC)-alpha activity by causing translocation of PKC-alpha from the membrane to the cytoplasm. These studies provide novel insights into the capacity of a reactive oxidant, such as H2O2, to modulate EGF-receptor function and its downstream signaling. The H2O2-induced increase in tyrosine phosphorylation of the EGF receptor, and the receptor's slower rate of turnover and altered downstream phosphorylation signals may represent a mechanism by which EGF-receptor signaling can be modulated during inflammatory processes, thereby affecting cell proliferation and thus having implications in wound repair or tumor formation.

Cytoskeletal integrity is required throughout the mitogen stimulation phase of the cell cycle and mediates the anchorage-dependent expression of cyclin D1

The proliferation of many nontransformed cells depends on cell adhesion. We report here that disrupting the cytoskeleton in normal human fibroblasts causes the same cell cycle phenotype that is observed after blocking cell adhesion: suspended cells and cytochalasin D-treated monolayers fail to progress through G1 despite normal mitogen-induced expression of c-myc mRNA. Midway between G0 and the beginning of S-phase, cell cycle progression becomes independent of adhesion and the cytoskeleton. At this stage, the cells are also mitogen independent. Molecular analyses showed that Rb hyperphosphorylation and the induction of cyclin D1 occur slightly earlier than the transition to cytoskeleton independence. Moreover, these molecular events are blocked by cytochalasin D. Overall, our data indicate the following: 1) anchorage and cytoskeletal integrity are required throughout the mitogen-dependent part of G1; 2) mitogens and the cytoskeleton jointly regulate the phosphorylation of Rb; and 3) this interdependence is manifest in the regulation of cyclin D1.

Effects of selected chemotherapeutic agents on PCNA expression in prostate carcinoma cell lines

Bivariate flow cytometric analysis of proliferating cell nuclear antigen (PCNA) was performed on prostate carcinoma cell lines (PC-3, DU-145). For both cell lines 100% methanol fixation provided optimal fluorescence intensity of PCNA. The ratio of PCNA/DNA increased in late G1 through early S/phase, followed by a decrease in mid- and late S and enhancement in G2/M phase. PCNA expression was increased in G2/M phase cells treated for 48 h with vinblastine. A slight decrease in PCNA expression was observed with cyclohexamide treatment. Hydroxyurea induced an increase in S-phase fraction along with enhanced PCNA expression. Methotrexate and Adriamycin had little effect on the cell cycle compartments of PC-3 or DU-145; however, methotrexate decreased PCNA expression, while Adriamycin enhanced it. Cisplatin increased S-phase in both cell lines, increasing PCNA expression in PC-3 and decreasing it in DU-145 cells. The data on the effects of drug treatment point to a dissociation between PCNA expression and S-phase fraction as calculated from the DNA distribution. In some cases, e.g., the cisplatin studies, different effects were obtained in the two different cell lines treated with the same drugs. Whether changes in PCNA expression will provide more useful information than S-phase fraction for evaluation of potential antitumor drugs is not known.

Discrimination of mitotic cells using anti-p105 monoclonal antibody to analyze the mode of action of etoposide and podophyllotoxin in human gastric cancer cells

Anti-p105 monoclonal antibody was used to discriminate between M-phase and G2-phase of gastric cancer cells. p105 is a proliferation-associated nuclear antigen and its expression increases with cell cycle progression, especially in the mitotic phase. As an example of cell cycle analysis, the modes of action of etoposide and podophyllotoxin were examined by multiparameter flow cytometry. We found that etoposide caused G2 block and retarded S phase transit and podophyllotoxin caused potential M phase block in gastric cancer cells. This cell cycle analysis by using anti-p105 monoclonal antibody should be useful for analysis of the actions of anti-tumor agents, especially for M phase analysis, because of its convenience and reliability.

Sodium-N-butyrate induces cytoskeletal rearrangements and formation of cornified envelopes in cultured adult human keratinocytes

The technique developed in our laboratory allows us to culture multilayered, stratified sheets of human keratinocytes, which can be used to cover the burn wounds of patients. Organization of cells in these cultures resembles stratum germinativum and stratum spinosum but there are only a few fully keratinized cells and the stratum corneum is not developed. Since the fully differentiated sheets may offer additional advantages as epidermal transplants, attempts were made to enhance the degree of differentiation in vitro. In the present study sodium-N-butyrate (NaB) was used as a differentiating agent and its effect on the cell cycle and cytoarchitecture of epidermal cells was investigated. Incubation of keratinocytes in the presence of 2.5 mM NaB induced the appearance of enucleated cornified envelopes, covering approximately 70-80% of the surface of the cultures. Their appearance correlated with a decrease in expression of keratin K13, previously shown to be inhibited during terminal differentiation of human keratinocytes. An increase in transglutaminase transferase activity was also observed. The induction of cornified layers also correlated with an increase in the amount of microfilament (MF)-associated actin. NaB also induced changes in the cell cycle distribution of the keratinocyte cultures. A decrease in the proportion of S and G1B phase cells was paralleled by an increase in G1A cells, maximally expressed 30-48 h following addition of the inducer. Interestingly, NaB also induced a cell arrest in G2 phase. These cell cycle perturbations preceded the onset of keratinocyte differentiation. The results indicate that the enhanced differentiation of human keratinocytes in the presence of NaB may serve as a means to produce epidermal sheets with improved properties for transplantation in a clinical setting. It also serves as an in vitro model system to study the interrelationships between biochemical events and cell cycle changes accompanying differentiation.

Cell cycle phase-specific perturbation of hepatic tumor cell growth kinetics during short-term in vitro exposure to ethanol

Cell cycle events associated with the growth suppressive effects of short-term ethanol exposure on liver cells were investigated using flow cytometric methods to analyze the proliferative kinetics of ethanol-sensitive 32IIIA rat hepatic tumor cells. A 3-day exposure of exponentially growing 32IIIA cells to growth medium containing 100 mM ethyl alcohol decreased final population density (to less than 70% of control values) although viability was unaffected, approximating 94% under all experimental conditions. Comparative flow cytometric analysis of control and ethanol-treated populations revealed significant ethanol-associated alterations in the substate composition of G1 phase hepatic tumor cells. An ethanol-induced 30% increase in mean population doubling time was reflected in an approximately 22% increase in the proportion of G1 phase cells within a culture. Lower overall G1 cellular RNA content typified all ethanol-treated 32IIIA tumor cell populations. The fraction of G1 cells in the immediate pre-DNA-synthetic (G1B) compartment was markedly reduced (by 41-80%) during the period of ethanol exposure as were the percentages of S and G2+M phase cells which derive kinetically from cells in G1B. This reduction in the proportion of cells with normal G1B RNA levels was not reflected solely in the complement of very low RNA content "G1E-type" cells generated during the course of ethanol treatment. Net accumulations (of 19 and 34%) of cells residing in the G1A substate were consistent additional concomitants of ethanol treatment. Short-term ethanol exposure in the 32IIIA hepatic tumor cell system clearly impairs normal progression of such cells through the G1 phase of the cell division cycle.(ABSTRACT TRUNCATED AT 250 WORDS)

In situ factors affecting stability of the DNA helix in interphase nuclei and metaphase chromosomes

The data from earlier cytochemical studies, in which the metachromatic fluorochrome acridine orange (AO) was used to differentially stain single vs double-stranded DNA, suggested that DNA in situ in intact metaphase chromosomes or in condensed chromatin of G0 cells is more sensitive to denaturation, induced by heat or acid, than DNA in decondensed chromatin of interphase nuclei. Present studies show that, indeed, DNA in permeabilized metaphase cells, in contrast to cells in interphase, when exposed to buffers of low pH (1.5-2.8) becomes digestible with the single-strand-specific S1 or mung bean nucleases. A variety of extraction procedures and enzymatic treatments provided evidence that the presence of histones, HMG proteins, and S-S bonds in chromatin, as well as phosphorylation or poly(ADP)ribosylation of chromatin proteins, can be excluded as a factor responsible for the differential sensitivity of metaphase vs interphase DNA to denaturation. Cell treatment with NaCl at a concentration of 1.2 N and above abolished the difference between interphase and mitotic cells, rendering DNA in mitotic cells less sensitive to denaturation; such treatment also resulted in decondensation of chromatin visible by microscopy. The present data indicate that structural proteins extractable with greater than or equal to 1.2 N NaCl may be involved in anchoring DNA to the nuclear matrix or chromosome scaffold and may be responsible for maintaining a high degree of chromatin compaction in situ, such as that observed in metaphase chromosomes or in G0 cells. Following dissociation of histones, the high spatial density of the charged DNA polymer may induce topological strain on the double helix, thus decreasing its local stability; this can be detected by metachromatic staining of DNA with AO or digestion with single-strand-specific nucleases.

In vivo cell kinetic effects of cis-platinum on human ovarian cancer xenografts measured by dual parameter flow cytometry

Dual parameter flow cytometry, measuring DNA and nuclear protein of individual cell nuclei simultaneously, makes it possible to follow cell kinetic perturbations in six distinct compartments of the cell cycle following chemotherapy in vivo. Human ovarian cancer xenografts in nude mice from a primary and recurrent tumor of the same patient were studied. The response to intraperitoneal application of cis-platinum was assessed by tumor volume measurements, changes in labeling indices by autoradiography, and dual parameter flow cytometry. Sequential tissue samples were taken from each tumor using fine needle aspirations as a microbiopsy method. Pretherapy samples were compared to multiple specimens collected up to 18 days after therapy. Morphologic changes of each specimen were also assessed. Cis-platinum affects malignant cells in the G1B, S, G2A, and G2B compartments with various intensities and different time frames, depending on the drug sensitivity of each individual tumor.

A flow cytometric study of DNA staining in situ in exponentially growing and stationary Euglena gracilis

DNA stainability by different fluorochromes has been compared in exponentially dividing and stationary Euglena cells. With the intercalating fluorochromes, ethidium bromide, acridine orange and DAPI, a decrease of fluorescence intensity of the G1 cells is observed when cells enter stationary stage. However this decrease of fluorescence is not obtained with the nonintercalating fluorochrome Hoechst 33258. If nuclear basic proteins are extracted, however, the intensity of staining by either Hoechst 33258 or ethidium-bromide is comparable in stationary and dividing cells. Therefore, the decrease of fluorescence intensity of the G1 cells observed during the transition from exponential to stationary phase is not due to a loss of DNA but is related to the exposure of chromatin binding sites for ethidium bromide. In Euglena cells, DNA accessibility for intercalating fluorochromes depends upon chromatin structure and consequently upon cell age.

Alterations in growth rate and cell cycle kinetics of rat liver tumor cells cultured in ethanol-containing medium. In vitro model of proliferative restriction in response to ethanol exposure

Mechanisms related to the growth suppressive effect of acute ethanol exposure on liver cells were investigated using an established line of ethanol-sensitive rat hepatic tumor cells (32IIIA) and recently developed cytochemical methods for analysis of hepatocyte cell cycle kinetics. Exposure of exponentially growing 32IIIA cells to ethyl alcohol (range 10-100 mM in the growth medium) for a period of 3 days resulted in concentration-dependent decreases (4-25%) in final population density and increases (18-35%) in mean population doubling time compared to untreated cells. Viability was unaffected by ethanol exposure in the concentrations indicated and for the duration period utilized, approximating 94% under all experimental conditions. Multiparametric flow cytometric analysis revealed significant ethanol-associated differences in specific growth parameters and growth state compartments of 32IIIA hepatic tumor cell populations. Most prominent was an ethanol-associated and concentration-dependent (a) increase in the fraction of cells in the G1 phase of the cell cycle, (b) increase in the coefficient of variation in the G1 DNA content measurement, and (c) accumulation (in the G1 phase) of cells with a very low mean RNA content. Increases in each of these cytochemically-defined parameters reflected increasing levels of ethanol in the growth medium. This study indicates that the effects of ethanol on cultured cells of hepatic origin are quite complex. It is concluded that the inhibition of proliferation observed during acute ethanol exposure of liver-derived 32IIIA cells in vitro is due to an accumulation of cells in the G1 compartment.

EGF induces cell cycle arrest of A431 human epidermoid carcinoma cells

The human carcinoma cell line A431 is unusual in that physiologic concentrations of epidermal growth factor (EGF) inhibit proliferation. In the presence of 5-10 nM EGF proliferation of A431 cells is abruptly and markedly decreased compared to the untreated control cultures, with little loss of cell viability over a 4-day period. This study was initiated to examine how EGF affects the progression of A431 cells through the cell cycle. Flow cytometric analysis of DNA in EGF-treated cells reveals a marked change in the cell cycle distribution. The percentage of cells in late S/G2 increases and early S phase is nearly depleted. Since addition of the mitotic inhibitor vinblastine causes accumulation of cells in mitosis and prevents reentry of cells into G1, it is possible to distinguish between slow progression through G1 and G2 and blocks in those phases. When control cells, not treated with EGF, are exposed to vinblastine, the cells accumulate mitotic figures, as expected, and show progression into S, thus diminishing the number of cells in G1. In contrast, no mitotic figures are found among the EGF-treated cells in the presence or absence of vinblastine, and progression from G1 into S is not observed, as the number of cells in G1 remains constant. These results suggest that there are two EGF-induced blocks in cell cycle transversal; one is in late S and/or G2, blocking entry into mitosis, and the other is in G1, blocking entry into S phase. After 24 hours of EGF treatment, DNA synthesis is reduced to less than 10% compared to untreated controls as measured by the incorporation of [3H]thymidine or BrdU. In contrast, protein synthesis is inhibited by about twofold. Although inhibition of protein synthesis is less extensive, it occurs 6 hours prior to an equivalent inhibition of DNA synthesis. The rapid decrease in protein synthesis may result in the subsequent cell cycle arrest which occurs several hours later.

Human keratinocyte culture. Identification and staging of epidermal cell subpopulations

Stratification of human epidermal cells into multilayered sheets composed of basal and suprabasal layers (resembling the stratum germinativum and stratum spinosum of the epidermis) was studied in a dermal component-free culture system. Although no stratum corneum developed in vitro, this culture system provided a method to study early events in human keratinocyte differentiation. Multiparameter flow cytometric analysis of acridine orange-stained epidermal cells from these cultures revealed three distinct subpopulations differing in cell size, RNA content, and cell cycle kinetics. The first subpopulation was composed of small basal keratinocytes with low RNA content and a long generation time. The second subpopulation consisted of larger keratinocytes, having higher RNA content and a significantly shorter generation time. Finally, the third subpopulation contained the largest cells, which did not divide, and represent the more terminally differentiated keratinocytes. This in vitro approach provides discriminating cytochemical parameters by which the maturity of the epidermal cell sheets can be assessed prior to grafting onto human burn patients.

RNA content and chromatin structure of CHO cells arrested in metaphase by colcemid

To evaluate the stability of cells arrested in metaphase, cell viability, RNA content, and chromatin structure (the latter probed by the DNA in situ sensitivity to acid-induced denaturation) were studied in uniform-age mitotic CHO cell populations maintained either at 37 degrees C (in the presence of Colcemid) or at 0-4 degrees C for up to 6 h. No significant changes in cell viability and RNA content were seen throughout the experiment for both groups of cells. The sensitivity of DNA in situ to denaturation was significantly increased during the initial 40 min of cell arrest in mitosis. However, no further chromatin changes for up to 6 h were evident regardless of whether cells were kept at 37 degrees C with Colcemid or at 0-4 degrees C in its absence. The data indicate that neither significant deterioration of metaphase cells nor progressive chromatin changes are expected during stathmokinesis experiments in vitro or during the metaphase cell arrest in cytogenetic studies lasting up to 6 h. Also, no RNA turnover can be detected in mitotic cells during this time interval.

Effects of [3H]UdR on the cell-cycle progression of L1210 cells

Tritium-labelled uridine [( 3H]UdR) perturbs progression of L1210 cells through the mitotic cycle. The main effect manifests as a slowdown or arrest of a portion of cells in G2 and is already observed 2 hr after addition of 0.5-5.0 microCi/ml of [3H]UdR into cultures. At 2.5-5.0 microCi/ml of [3H]UdR a slowdown of cell progression through S is also apparent. Additionally, there is an increase in the number of cells with DNA values higher than 4C in cultures growing in the presence of [3H]UdR for 8-24 hr. A pulse of [3H]UdR of 2 hr duration labels predominantly (95%) cellular RNA. The first cell-cycle effects (G2 slowdown) are observed when the amount of the incorporated [3H]UdR is such that, on average there are fewer than thirty-six [3H] decays per cell which corresponds to approximately 12-19 rads of radiation. The S-phase slowdown is seen at a dose of incorporated [3H]UdR twice as high as that inducing G2 effects. The specific localization of [3H]UdR in nucleoli, peripheral nucleoplasm and in cytoplasm, as well as differences in the kinetics of the incorporation in relation to phases of the cell cycle are discussed in the light of the differences between the effects of [3H]UdR and [3H]thymidine. Mathematical modelling of the cell-cycle effects of [3H]UdR is provided.

Effects of a prospective antitumor agent, 1,4-bis(2'-chloroethyl)-1,4-diazabicyclo-[2.2.1] heptane diperchlorate, on cultured mammalian cells

The effects of 1,4-bis(2'-chloroethyl)-1,4-diazabicyclo-[2.2.1] heptane diperchlorate (CBH; NSC 57198) on cell viability, growth, progression through the cell cycle, survival, and differentiation were investigated in suspension cultures of murine lymphocytic leukemia (L1210) and erythroleukemic (FL) cells and normal human lymphocytes stimulated with phytohemagglutinin (PHA) and in adherent cultures of Chinese hamster ovary (CHO) cells. CBH was equally cytotoxic toward stationary and exponentially growing CHO cells. Cell viability was diminished by 50% following 24 hr exposure to approximately 50 micrograms CBH per ml. Treatment of quiescent human lymphocytes for 24 hr with up to 100 micrograms CBH per ml did not appreciably diminish cell viability though the subsequent stimulation of such lymphocytes with PHA was inhibited in a dose dependent fashion. L1210, FL cells, and PHA stimulated human lymphocytes were equally sensitive to CBH, 50% inhibition of growth was obtained following 24 hr treatment with 25 micrograms CBH per ml. Incubation for up to 48 hr with CBH did not result in differentiation of FL cells to mature hemoglobin containing cells. Constant exposure of L1210 cells and PHA-stimulated human lymphocytes to 10-50 micrograms CBH per ml resulted in accumulation of cells in G2 + M phase; higher drug concentrations resulted in cell arrest in mid to late S phase and G2 phase. A short 1-hr pulse of the drug resulted in a transient accumulation of L1210 cells in S and G2 phases. However, cells recovered from a short pulse of drug and by 48 hr, both cell proliferation and the cell cycle distribution appeared normal. A detailed analysis of cell cycle progression of L1210 cells in the presence of the drug indicated that the duration of G2 phase was extended at low concentrations (10 micrograms/ml) while the transit of cells through S was retarded with subsequent accumulation in late S and G2 phase at higher (50 micrograms/ml) concentrations. Concomitant with cell arrest in S and G2 phase an increase in cellular RNA content indicating unbalanced growth was observed. This state of unbalanced growth was reversible in cultures exposed to a 1-hr pulse of up to 100 micrograms CBH per ml; cellular RNA content returned to control values by 48 hr. No effect on nuclear chromatin as assayed by acid denaturation was observed. Though the exact mechanism of drug action is not known, the data are not incompatible with the drug acting as an alkylating agent.

Perturbations of cell-cycle progression in gamma-irradiated ataxia telangiectasia and Huntington's disease cells detected by DNA flow cytometric analysis

The effects of ionizing radiation on cell-cycle progression in lymphoblastoid cell lines derived from ataxia telangiectasia (AT) and Huntington's disease (HD) patients, and from normal individuals, were studied using DNA flow cytometric analysis. A dose of 100 rad gamma irradiation blocked a proportion of normal and HD cells in G1. A higher radiation dose applied to normal cells increased the number of cells blocked in G1 and significantly delayed cells which were in S at the time of irradiation from reaching G2 DNA content. The reduced cumulative mitotic index in irradiated cultures of normal cells 2 h after irradiation suggests that cells in G2 at the time of irradiation are delayed before entering mitosis. After irradiation HD cells responded similarly to normal cells except that a greater proportion of HD cells were blocked in G1. AT cells do not show the normal delay in progression from G1 to S, or from S to G2 in the first cycle after irradiation. The cumulative mitotic index was reduced in irradiated cells, implying that they are delayed in G2. Thus AT cells did not recognize or respond to signals from damaged DNA which in normal and HD cells caused a proportional block in G1 and an S-phase delay. The only point of arrest in cell-cycle progression in irradiated AT cells was in G2.

Do all daughter cells enter the "indeterminate" ("A") state of the cell cycle? Analysis of stathmokinetic experiments on L1210 cells

The results of ten different stathmokinetic experiments on L1210 cells are analyzed to determine whether all the postmitotic cells enter the exponential AG1 compartment of the cell cycle characterized by exponentially distributed transit times. The analysis is based on a mathematical model coherent with the generalized A-B-transition hypothesis. An original fitting procedure is introduced to estimate the fraction of cells entering AG1 as well as other parameters of the cell cycle. Results of the analysis suggest that either all or nearly all postmitotic cells enter G1A. The results are discussed with respect to the validity of the A-B-transition hypothesis of the "probabilistic" model of the cell cycle. Some systematically occurring discrepancies that do not conform with generally accepted cell cycle models are apparent from the analysis of this data.

Maturation rates and transition probabilities of cycling cells

The kinetics of cell cycling are analyzed in terms of equations incorporating a DNA synthesis rate continuously varying along S phase and a portion of G1 phase through which the cells advance in a probabilistic fashion. These equations are solved analytically for several steady state as well as nonsteady state populations of cells. Experiments are described illustrating how these results can be applied to obtain both the rate of DNA synthesis at each point along S-phase and the probability of transition through the nondeterministic portion of G1.

Secretion of albumin and alpha-foetoprotein by dimethylsulphoxide-stimulated hepatocellular carcinoma cells

Exposure of BW77-1 and BW77-2 mouse hepatic tumour cells to the polar solvent dimethylsulphoxide (DMSO) altered extracellular accumulation of albumin and alpha-foetoprotein (AFP) and perturbed their cell cycle kinetics. The amount of albumin secreted into the culture growth medium was dependent on the concentration of DMSO used. Hepatic tumour cells cultured in 1 and 2% DMSO accumulated 50% and 111% more albumin, respectively, than non-DMSO-stimulated cells during the final 24 h of a 4-day exposure to the polar solvent. Commitment of mouse hepatoma cells to increased albumin secretion was temporally dependent, requiring a minimum of 48 h in the presence of DMSO. The AFP level in 1% DMSO-treated cultures was also significantly increased, compared with control cells. Unlike albumin secretion, however, exposure of hepatic tumour cells to 2% DMSO did not further increase (but slightly decreased) extracellular AFP accumulation. Treatment of BW77-1 cells with DMSO resulted in a gradual decline in the percentage of 2C DNA content cells (diploid G1 population) and in a corresponding increase in the proportion of cells with a 4C DNA content (generation of either a G2 or tetraploid G1 population). The extent of this shift directly reflected the concentration of polar solvent in the medium and paralleled the DMSO-induced stimulation in albumin secretion. DMSO-stimulated hepatic tumour cells, therefore, may prove useful in the elucidation of specific regulatory events underlying control of gene expression during the hepatocyte cell cycle.

The ratio of RNA to total nucleic acid content as a quantitative measure of unbalanced cell growth

Use of the metachromatic dye, acridine orange, to stain cells in suspension for flow cytometry allows for the simultaneous measurement of DNA and RNA content in individual cells. The relative RNA content as a function of total cellular nucleic acid content [alpha r = RNA/(RNA + DNA)] is a constant value, characteristic for particular cell lines during their exponential growth under optimal conditions. This ratio can be estimated for the G1A, G1B, S, and G2 + M cell cycle compartments. Changes in growth rate or the addition of antitumor drugs induces characteristic changes in the ratio either evenly throughout or at a particular phase of the cell cycle. Under such conditions, measurement of cellular DNA and RNA content provides a sensitive assay of any deviation from balanced cell growth. Unbalanced growth caused by suboptimal culture conditions or as a result of incubation with various antitumor agents is illustrated. Examples of unbalanced growth which are not correlated with cell viability as measured by cell clonogenicity are discussed.

Flow cytometry and cell proliferation kinetics

Flow cytometric techniques are presented which allow to determine parameters of cell proliferation kinetics by means of histogram sequences after special manipulations of the cell culture under investigation: (a) In the stathmokinetic method metaphase blocking agents are applied which allow the cells of the population to continue progression through interphase and accumulate at 4C DNA content. The development of DNA specific histograms during this process is analysed as to the G1 phase duration and the fraction of nonproliferating cells. (b) In the BUdR/Hoechst method the suppression of Hoechst fluorescence after BUdR incorporation during S phase is taken as a means for inducing a temporal change of histogram shapes without perturbing the cell cycle progression of the population. This temporal development of histogram shapes is analysed as to phase duration, whole cycle time and fraction of nonproliferating cells. (c) By combining the BUdR/Hoechst technique with a simultanous DNA specific stain and analysing with a two-parametrical flow cytometer, more information is obtained from each histogram after BUdR incorporation: The location of cells in the cycle at the beginning of the experiment, the cycle stage at cell harvest, and from this the distance and velocity of progression through the cycle during drug incubation. By introduction of these dynamic methods flow cytometry has become a powerful tool for the study of cell proliferation kinetics in culture.

Combination of BUdR-quenched Hoechst fluorescence with DNA-specific ethidium bromide fluorescence for cell cycle analysis with a two-parameter flow cytometer

Stimulated or asynchronous L-cells were grown in a BUdR-medium, harvested and stained with a combination of 33258 Hoechst and ethidium bromide for analysis in a FACS II cell sorter. The u.v. laser line served as a light source for exciting the Hoechst fluorescence, the ethidium bromide fluorescence being excited mainly by energy transfer from the Hoechst dye. The quenched Hoechst fluorescence was analysed between 410 nm and 480 nm, the DNA specific EB fluorescence at beyond 630 nm. Thus, not only the actual location of each cell in the cycle could be determined, but also its initial location at time 0 of the experiment, together with its moment of division (BUdR-quenched Hoechst fluorescence). This method could become a powerful tool in many investigations dealing with cell cycle perturbations in culture.