Morphometric analysis of B2cAMP-induced reverse transformation in synchronized CHO cells

Summary Synchronized transformed and reverse-transformed (by 10⁻³ M B₂cAMP) CHO-K1 cells, growing adherent to plastic, are characterized by means of geometric and densitometric parameters at the level of both the entire cell and of the nuclei at various time intervals after selective mitotic detachment. Transformed and reverse-transformed cells triple-stained with Feulgen, Napthol Yellow S, and periodic acid-Schiff appeared very similar in terms of integrated optical density (IOD), related to either polysaccharides, protein, or DNA amount. On the other hand, a shift from a polygonal to a spindle-shaped morphology is accompanied by a significant decrease in both form factor and average optical density (AOD) of intact cell and nuclei, which are the most conspicuous measured changes caused by B₂cAMP, in addition to a lengthening of the cell cycle duration. In both control and treated cells, important and parallel cell-cycle-dependent modulations of geometric and densitometric parameters are also observed, for both the cytoplasmic (i.e., cell morphometry) and DNA space (i.e., nuclear morphometry). Specifically, the modulation in nuclear morphometry during G1, S, G2, andM phases confirms previous findings on synchronized HeLa cells. The optical density threshold-dependence of geometric parameters shows that, while becoming fusiform, the cytoplasm of reverse-transformed cells had a particularly low optical density precisely in the polar area. Utilization of such an approach in the development of anobjective morphological classification of all cell lines grown as monolayers “in vitro” is also discussed.     

Coupling of nuclear morphometry to cell geometry and growth in human fibroblasts

The nuclear morphology of WI-38 cells plated on increasing thicknesses of the polymer, poly-2-hydroxyethylmethacrylate, was studied. Changes in nuclear morphometry were found to parallel changes in cellular morphometry: namely a transition to a more rounded and compact conformation, with increasing thicknesses of the polymer. Such changes in nuclear morphometry were opposite to those already observed after stimulation of proliferation by serum addition and similar to those observed with increasing confluency. These results suggest that coupling between cell and nuclear geometry may represent a mechanism for the control of proliferation by cell shape in nontransformed cells.     

Normal versus abnormal cell proliferation

The most recent findings on the molecular and cellular characterization of normal and abnormal cell proliferation are summarized. They include molecular spectroscopy, nucleic acid conformation, protein modifications, premature chromosome condensation, nuceoli changes, nuclear and cell morphometry, image analysis, flow microfluorimetry, and time-lapse cinematography. Biophysical and biochemical evidence in favor or against two cycles of chromatin condensation, followed by two abrupt random decondensations, per cell cycle are presented. Other biphasic changes at the molecular and cellular levels that favor the existence of two random transitions, or restriction points, per cell cycle are discussed. A comprehensive unitary model of the cell cycle is then outlined; this model is able to explain most findings on continuously dividing cells and on quiescent cells induced to proliferate. Within this analytical framework the physical-chemical and biological properties are given, in either normal or tumor cells, for the various types of “noncycling” cells that are here viewed as necessary steps in mammalian cell growth rather than separate states. The implications of the coupling of higher-order chromatin structure with cell geometry and growth, high in fibroblast-like cells but low in transformed cells, are also discussed. Molecular mechanisms likely responsible for the chromatin conformational changes occurring at the G₀→G₁, G₁→S, G₂→M transitions are finally discussed in terms of polyelectrolyte theory.     

Nucleus image properties and cell death in MCF-10F cells grown on slide substrates differing in nature and size

Summary The immortalized human breast epithelial cell line MCF-10F is an important tool for studies on experimental tumorigenesis induced by drugs, transfected Ha-ras oncogene, and hormones. Considering that many relevant data have thus far been established only for MCF-10F cells cultivated on glass, and that there are data showing different cell death ratios for tumorigenic cells obtained from benzo[a]pyrene (BP)-transformed MCF-10F cells cultivated on plastic compared with glass, nuclear parameters estimated by image analysis and cell death ratios were compared for cells grown on plastic and glass substrates differing in chamber surface sizes and working culture medium volumes. It was concluded that for slides with a growth size equal to 9.4 cm², plastic substrate was more advantageous than glass for growing MCF-10F cells because although the apoptotic ratios (AR) for the cells grown on plastic are low as it would be expected for nontransformed cells, they are bigger than those reported for the BP-transformed MCF-10F cells cultivated on the same substrate but closer to those of the BP-transformed MCF-10F cells receiving a normal chromosome 17. In addition, the plastic substrate did not induce variable nuclear image results as those found in the latter. The 0.5-cm²-sized chambers on plastic slides proved to be inadequate for cell nuclear image analysis and cell death studies on account of the variable geometric, densitometric, and textural results and ARs produced and the unpublished consideration of a very slow growth rate generated under this growth condition.     

Normal versus abnormal cell proliferation. A unitary and analytical overview

The most recent findings on the molecular and cellular characterization of normal and abnormal cell proliferation are summarized. They include molecular spectroscopy, nucleic acid conformation, protein modifications, premature chromosome condensation, nucleoli changes, nuclear and cell morphometry, image analysis, flow microfluorimetry, and time-lapse cinematography. Biophysical and biochemical evidence in favor or against two cycles of chromatin condensation, followed by two abrupt random decondensations, per cell cycle are presented. Other biphasic changes at the molecular and cellular levels that favor the existence of two random transitions, or restriction points, per cell cycle are discussed. A comprehensive unitary model of the cell cycle is then outlined; this model is able to explain most findings on continuously dividing cells and on quiescent cells induced to proliferate. Within this analytical framework the physical-chemical and biological properties are given, in either normal or tumor cells, for the various types of "noncycling" cells that are here viewed as necessary steps in mammalian cell growth rather than separates states. The implications of the coupling of higher-order chromatin structure with cell geometry and growth, high in fibroblast-like cells but low in transformed cells, are also discussed. Molecular mechanisms likely responsible for the chromatin conformational changes occurring at the G0 leads to G1, G1 leads to S, G2 leads to M transitions are finally discussed in terms of polyelectrolyte theory.     

Morphometric analysis of B2cAMP induced reverse transformation in synchronized CHO cells.

Synchronized tranformed and reverse-transformed (by 10(-3) M B2cAMP) CHO-K1 cells, growing adherent to plastic, are characterized by means of geometric and densitometric parameters at the level of both the entire cell and of the nuclei at various time intervals after selective miotic detachment. Transformed and reverse-transformed cells triple-stained with Feulgen, Napthol Yellow S, and periodic acid-Schiff appeared very similar in terms of integrated optical density (IOD), related to either polysaccharides, protein, or DNA amount. On the other hand, a shift from a polygonal to a spindle-shaped morphology is a accompanied by a significant decrease in both form factor and average optical density (AOD) of intact cell and nuclei, which are the most conspicuous measured changes caused by B2cAMP, in addition to a lengthening of the cell cycle duration. In both control and treated cells, important and parallel cell-cycle-dependent modulations of geometric and densitometric parameters are also observed, for both the cytoplasmic (i.e., cell morphometry) and DNA space (i e., nuclear morphometry). Specifically, the modulation in nulear morphometry during G1, S, G2, and M phases confirms previous findings on synchronized HeLa cells. The optical density threshold-dependence of geometric parameters shows that, while becoming fusiform, the cytoplasm of reverse-transformed cells had a particularly low optical density precisely in the polar area. Utilization of such an approach in the development of an objective morphological classification of all cell lines grown as monolayers "in vitro" is also discussed.     

Cyclic nucleotides and cell growth

Growth induction in resting fibroblast cultures by serum or growth factors induces a fast, transient cGMP peak which may constitute the intracellular signal for growth. A similar cGMP peak occurs when 3T3 cells arrested at the restriction point or in G₀ by starvation for certain amino acids are induced for growth by readdition of the lacking nutrients. Both 3T3 and SV3T3 cells which are arrested randomly all around the cell cycle do not exhibit major changes in cyclic nucleotides after growth induction. Determination of intracellular cAMP and cGMP levels in normal and transformed fibroblasts under different growth conditions shows that the transition between growing and resting state (G₀ arrest) is accompanied and probably induced by characteristic changes in cAMP to cGMP ratios. cGMP is decreased 2-5-fold in resting as compared to growing cultures, and increased 10-20-fold in activated cultures 20 min after serum induction. No major cGMP change was observed in growing, confluent, or serum-activated cultures of transformed cells. Measurement of guanylcyclase under unphysiological conditions (2 mM Mn⁺⁺) in crude and purified membranes from 3T3 and SV3T3 cultures did not show increased enzyme activity in the transformed cells. Significant differences may only show up when synchronized cells pass through the restriction point in G₁ phase. As a hypothesis it is proposed that transformed cells have an activated guanylcyclase system or a relaxed cGMP-pleiotypic response mechanism at the restriction point of their cell cycle.     

Effects of sugars on the physiology of cultured fibroblasts

Pronounced, rapid, and reversible changes in cultured normal and transformed fibroblasts are observed following removal of sugars from the culture medium. Growth immediately ceases or greatly diminishes; it resumes at a normal rate without any appreciable delay following re-addition of glucose. The cell shape changes within 6 h to a more flattened and elongated form similar to that of cells treated with db-cAMP. The NAD⁺/NADH ratio rises 4-fold and the ATP level falls about 25% in 2 h; however, the cAMP level remains constant. In transformed mouse SVT2 cells, other sugars will not replace glucose. A variant line of SVT2 (SVT2 SUG⁺) which will grow on numerous sugars has been isolated. Its growth rate, morphology and adhesion to the substratum, but not cAMP content, are dependent upon the sugar composition. These results suggest that the sugar composition of the growth medium has pronounced effects on cell physiology and that the effects are not mediated by cAMP.     

Cell junction and cyclic AMP: II. Modulations of junctional membrane permeability,dependent on serum and cell density

Summary Junctional molecular transfer (as indexed by the number of cell interfaces transferring fluorescent-labelled molecules) and concentration of endogenous cAMP were determined in mammalian cells in culture at varying serum concentration and cell density. In several cell types, on stepping the serum concentration from 10% (the concentration to which the cells had been adapted) to zero, the junctional transfer rose (reversibly) within 48 hr, as the endogenous cAMP concentration rose. The junctional transfer was inversely related to serum concentration over a range, most steeply so the transfer of large and charged molecules. one cell type showed no junctional change in response to serum; it showed also no endogenous cAMP change. Junctional transfer varied inversely with cell density over the range of 0.7–7 (10⁴ cells/cm²) in 3T3 cells. In cultures seeded to various densities, or growing to various densities on their own, junctional transfer fell with rising density, and so did the endogenous cAMP concentration. Upon downstep from high density, junctional transfer rose over 24–48 hr. In B cells, junctional transfer was independent of cell density over the aforementioned range, and so was the endogenous cAMP concentration. These results, in conjunction with the effects of exogenous cAMP described in the preceding paper of this series, point to a cAMP-mediated junctional effect; a possible teleonomy for control of membrane junction is discussed.     

Micropatterning of single endothelial cell shape reveals a tight coupling between nuclear volume in G1 and proliferation

Shape-dependent local differentials in cell proliferation are considered to be a major driving mechanism of structuring processes in vivo, such as embryogenesis, wound healing, and angiogenesis. However, the specific biophysical signaling by which changes in cell shape contribute to cell cycle regulation remains poorly understood. Here, we describe our study of the roles of nuclear volume and cytoskeletal mechanics in mediating shape control of proliferation in single endothelial cells. Micropatterned adhesive islands were used to independently control cell spreading and elongation. We show that, irrespective of elongation, nuclear volume and apparent chromatin decondensation of cells in G1 systematically increased with cell spreading and highly correlated with DNA synthesis (percent of cells in the S phase). In contrast, cell elongation dramatically affected the organization of the actin cytoskeleton, markedly reduced both cytoskeletal stiffness (measured dorsally with atomic force microscopy) and contractility (measured ventrally with traction microscopy), and increased mechanical anisotropy, without affecting either DNA synthesis or nuclear volume. Our results reveal that the nuclear volume in G1 is predictive of the proliferative status of single endothelial cells within a population, whereas cell stiffness and contractility are not. These findings show that the effects of cell mechanics in shape control of proliferation are far more complex than a linear or straightforward relationship. Our data are consistent with a mechanism by which spreading of cells in G1 partially enhances proliferation by inducing nuclear swelling and decreasing chromatin condensation, thereby rendering DNA more accessible to the replication machinery.     

Differentiation of the guinea pig eye: Nuclear ultrastructure,template activity and DNA content

Summary Nuclei of various cell types in the eye of embryonal and adult Guinea pigs were studied by means of electron microscopy, cytophotometry and autoradiography. Striking differences in condensation and arrangement of chromatin were found between the different tissues and cells. Several nuclear types were analyzed quantitatively with regard to their content of condensed and decondensed chromatin by means of electron microscopic morphometry. Structural differences in chromatin organization coincided with different nuclear DNA contents in various cell types of the retina, such as bipolar cells, Müller cells, rods and cones, and the pigmented epithelium.The differences between DNA-Feulgen means obtained by cytophotometric analysis were highly significant. Template activity as shown by³H-uridine incorporation made evident that the rate of RNA synthesis is positively correlated with the quantity of decondensed chromatin. It is speculated that differentiation of the Guinea pig eye involves differential DNA synthesis, and that the extra-DNA could have some trigger function for the pattern of chromatin condensation and thus the pattern of gene expression.     

The relation of endogenous adenosine cyclic 3':5'-monophosphate to the antagonistic effects of adenosine and colchicine on cell shape.

Adenosine and colchicine have antagonistic effects on cell shape. When Chinese Hamster lung fibroblasts (CHE36-6) or SV40 transformed 3T3 (SV3T3) cells are incubated with colchicine (1 muM) for one hour at 37 degrees C, they round up into spheres with short spikes. Cells treated with adenosine (1 muM-minus 4 mM) for one hour become refractile and develop spindly processes. However, when the two compounds are added simultaneously, the characteristic responses to either drug are abolished and the cells appear normal. The counteraction is specific for adenine and its derivatives, adenosine being the most effective of the compounds we tested. Accumulation of colchicine or adenosine is not altered significantly by the presence of the other drug, ruling out decreases in uptake as the basis of the mutual antagonism. The morphological changes can be observed under conditions where there are no changes in intracellular cAMP levels (such as incubation with low concentrations of adenosine or cordycepin, an adenosine analog that cannot be directly converted to cAMP). Colchicine does not alter cAMP content of control or adenosine-treated cells. These data show that adenine compounds have potent effects on cell shape, and the antagonistic effects of adenosine and colchicine on cell shape are not mediated through changes in intracellular cAMP levels.     

Surface charge and cell volume of synchronized mouse lymphoblasts (L5178-Y)

Cellular electrophoretic mobility, and therefore, surface charge/ unit area, was found to be constant throughout the cell cycle of synchronized L5178-Y mouse lymphoblasts, remaining at – 1.21 μ sec^?1 V^?1 cm. Measured cell volumes of these synchronized cells increased linearly over the cell cycle and at mitosis each cell divided into two cells, each cell having half of the parent volume. An hypothesis is presented which explains the presence of a mobility peak at mitosis in cells which normally are grown attaching to a glass surface on the basis of differential morphological changes during mitosis; cells such as the L5178-Ys, which do not attach to glass normally, do not undergo such morphological changes at mitosis and, therefore, would not demonstrate a mobility peak at that time.     

Inhibition of neoplastic cell growth by quiescent cells is mediated by serum concentration and cAMP phosphodiesterase inhibitors

We have demonstrated that confluent monolayers of the mouse fibroblast cell line C3H/10T1/2 (10T1/2) have the ability to cause reversible growth inhibition of cocultured transformed cells. This was first demonstrated for de novo transformed cells and later extended to established cell lines of proven oncogenicity in vivo. This growth inhibition could be increased by growing the 10T1/2 cells to high density in increasing concentrations of serum or by elevating intracellular concentrations of cAMP using inhibitors of phosphodiesterase (PDE). These manipulations, which in cocultures of nontransformed and transformed cells caused complete inhibition of tumor cell growth, had no effect on growth rate or saturation density of either ceil type when cultured alone, demonstrating the cooperative nature of this phenomenon. This cooperation could not be produced by transfer of culture medium, demonstrating the requirement for intimate cell contact. Inhibition of the formation of transformed foci of cells in these mixed cultures was accompanied by a decrease in the incorporation of labeled thymidine into these cultures; the kinetics of this inhibition and recovery suggested a rapidly reversible effect on cell cycle transit times. The potent inhibitor of cAMP PDE, Ro 20-1724 induced dose dependent increases in intracellular cAMP in both nontransformed and in transformed cells. However, at a concentration of 10^?4 M Ro 20-1724, which inhibited tumor cell growth in mixed cultures, cAMP was elevated 30-fold in nontransformed versus only 3-fold in transformed cells. The inhibitory effects of PDE inhibitors on tumor growth have been extended to an in vivo model system, utilizing Lewis lung carcinoma cells growing as metastases in the lungs of C57B1 mice. In these mice, inoculated intravenously with a single cell suspension of Lewis lung cells, the formation of lung metastases was dramatically decreased by the twice daily administration of either isobutylmethylxanthine or Ro 20-1724; PDE inhibitors were shown to be active in vitro. The latter compound, which showed highest activity in vitro, was also substantially more potent in vivo as an inhibitor of lung tumor colony formation and doubled the life span of the tumor bearing animals. Cell cycle analysis of lung tumor colonies by the labeled mitosis method showed that both phosphodiesterase inhibitors caused a prolonged G₁ phase in the cell cycle but failed to influence other phases. Although detailed analysis of host tissues is not complete, prolonged treatment with these drugs caused no statistically significant weight loss or changes in counts of red or white blood cells indicating a selective growth inhibition of transformed cells at these doses. Studies to determine the mechanism of the cellular communication and the nature of the signal are in progress.     

cAMP levels in proliferating rat mammary epithelial cells in vitro and in vivo

Agents that elevate intracellular cAMP levels are required for growth of many cell types in culture including normal rat mammary epithelial (RME) cells. To determine if the intracellular levels of cAMP that result from stimulation by agents such as cholera toxin (CT) or prostaglandin E-1 (PGE-1) are within the physiological range, cAMP levels were determined in RME cells growing in primary culture and compared to levels measured in freshly isolated mammary epithelium. The results indicate that the cAMP levels of mammary epithelial organoids obtained from 45-day-old virgin rats are 4 to 6 pmol/10⁶ cells. Growth of RME cells in primary culture in the presence of CT results in cAMP levels of approximately 15 to 20 pmol/10⁶ cells early in culture when cells are proliferating rapidly. As cells approach confluence, cAMP concentrations decrease to levels observed in fresh organoids. CT-stimulated cAMP levels appear to be within the range of those found in pregnant mammary epithelium in vivo. Growth of RME cells in medium supplemented with PGE-1 instead of CT results in cAMP levels equivalent to those found in fresh mammary epithelial organoids and under these conditions the growth rate is approximately half that found in CT-stimulated cells. These results indicate cAMP to be a positive regulator of cell growth in vivo at levels that are within the physiological range.     

Relationship between cyclic AMP, microtubule organization, and mammalian cell shape : Studies on Chinese hamster ovary cells and their variants

Treatment of Chinese hamster ovary cells with N⁶,2′-O-dibutyryl adenosine cyclic 3′,5′-monophosphate (db-cAMP) and hormones converts their shape from a knobbed, epithelial-like morphology to a smooth fibroblast-like form. Ultrastructural studies demonstrate an increased number of microtubules and their arrangement in parallel array along the long axis of the cell after treatment with these agents. Although an epithelial-like variant, when treated with db-cAMP, shows an increase in the number of microtubules; these microtubules remain in a disorganized nonparallel array. The numerous long microtubules which are already present in a fibroblast-like variant become further elongated when the cells are treated with db-cAMP. These experiments establish the relationship between cAMP level, assembly and organization of microtubules, and cell shape in cultured Chinese hamster cells.     

Alteration in gene expression at the onset of human Y-79 retinoblastoma cell differentiation

We have tested the hypothesis that differentiation and growth arrest of Y-79 human retinoblastoma cells in culture is associated with a modification of gene expression. We first examined proteins translated from mRNAs isolated from Y-79 cells growing in suspension and in attachment cultures in serum-containing medium and found them to be markedly different. This suggests that membrane-substrate interactions are of major consequence in the biochemical differentiation of these cells. Secondly, we examined the patterns of proteins translated from attached cells which had been induced to morphologically differentiate into neuronal-like and glial-like cells by serum-withdrawal and dibutyryl cAMP treatment respectively. The in vitro translatable proteins of mRNAs isolated from these cultures were found to be markedly different from those of the suspension and attachment cultures. Thirdly, we found that treatment of cells growing in attachment culture in serum-containing medium supplemented with 8-bromo cAMP, butyrate and retinoic acid as well as dibutyryl cAMP resulted in discreet alterations in proteins translated in vitro from extracted mRNAs. Although all these substances inhibit the growth of Y-79 cells, only dibutyryl cAMP and butyrate result in morphological differentiation of cells. Our results suggest that (1) attachment and morphological differentiation of Y-79 cells are both related to specific alterations in gene expression and (2) differentiation and inhibition of cell growth by various agents can be correlated with changes in translatable mRNA species although all agents do not act in the same mode.     

cAMP-mediated increase in the critical cell size required for the G1 to S transition in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, cyclic AMP is required for cellular growth. In this study we show that cAMP also specifically inhibits the G1-S transition of the S. cerevisiae cell cycle by increasing the critical cell size required at start, the major yeast cell cycle control step. In fact: (a) addition of cAMP delays the time of entering into the S budded phase of small G1 cells, while it is ineffective on large fast-growing cells. (b) If cell growth is strongly depressed, cAMP permanently inhibits cell cycle commitment of cells arrested at the α-factor-sensitive step. The cell fraction inhibited by cAMP is inversely correlated with the average cell size of treated populations. (c) The critical protein content (P_s) and the critical cell volume (V_B) required for budding in unperturbed exponentially growing yeast populations are largely increased by cAMP. On these bases, we propose a new cAMP role at start.     

Apoptosis of syncytia induced by the HIV-1-envelope glycoprotein complex: influence of cell shape and size

Cells stably transfected with a lymphotropic HIV-1 Env gene form syncytia when cocultured with CD4(+)CXCR4(+) cells. Heterokaryons then spontaneously undergo apoptosis, while manifesting signs of mitochondrial membrane pemeabilization as well as nuclear chromatin condensation. Modulation of cellular geometry was achieved by growing syncytia on self-assembled monolayers of terminally substituted alkanethiolates designed to control the adhesive properties of the substrates. Spreading of syncytia, induced by culturing them on small circular adhesive islets (diameter 5 microm), placed at a distance that cells can bridge (10 microm), inhibited spontaneous and staurosporin-induced signs of apoptosis, both at the mitochondrial and at the nuclear levels, and allowed for the generation of larger syncytia. Transient cell spreading conferred a memory of apoptosis inhibition which was conserved upon adoption of a conventional cell shape. Limiting syncytium size by culturing them on square-shaped planar adhesive islands of defined size (400 to 2500 microm(2)), separated by nonadhesive regions, enhanced the rate of apoptotic cell death, as indicated by an accelerated permeabilization of the outer mitochondrial membrane, loss of the mitochondrial inner transmembrane potential, and an increased frequency of nuclear apoptosis. In conclusion, external constraints on syncytial size and shape strongly modulate their propensity to undergo apoptosis.