Cell-cycle analysis of fission yeast cells by flow cytometry

The cell cycle of the fission yeast, Schizosaccharomyces pombe, does not easily lend itself to analysis by flow cytometry, mainly because cells in G(1) and G(2) phase contain the same amount of DNA. This occurs because fission yeast cells under standard growth conditions do not complete cytokinesis until after G(1) phase. We have devised a flow cytometric method exploiting the fact that cells in G(1) phase contain two nuclei, whereas cells in G(2) are mononuclear. Measurements of the width as well as the total area of the DNA-associated fluorescence signal allows the discrimination between cells in G(1) and in G(2) phase and the cell-cycle progression of fission yeast can be followed in detail by flow cytometry. Furthermore, we show how this method can be used to monitor the timing of cell entry into anaphase. Fission yeast cells tend to form multimers, which represents another problem of flow cytometry-based cell-cycle analysis. Here we present a method employing light-scatter measurements to enable the exclusion of cell doublets, thereby further improving the analysis of fission yeast cells by flow cytometry.     

Cell-cycle parameters of soybean (Glycine max L.) cells growing in suspension culture: Suitability of the system for genetic studies

Summary Suspension cultures of Glycine max (L.) Merr. were grown at 22 and 33°. The doubling times of dividing cells were 35 and 25 h, respectively. G₂ was 6.2 and 6.7 h, and S was 13.8 and 6.5 h. G₁ was calculated as 13 and 10 h, respectively. These values were determined by labeling cells with ³H thymidine and measuring the appearance of radioactive mitotic figures. Treatment with 5-fluorodeoxyuridine (FudR) inhibited DNA synthesis and, as a result, cells accumulated in S. Such cells were viable and, upon removal of the FudR, proceeded synchronously into mitosis. Treatment with 5-bromodeoxyuridine, following FudR synchronization, sensitized the cells to white light. Thus cells capable of synthesizing DNA could be killed. 20–30% of the cells in suspension cultures growing at 22 or 33° were not able to synthesize DNA. Nevertheless, these non-dividing (Q) cells were able to synthesize RNA and protein at a reduced rate. The proteins synthesized appear to be a particular subset of the proteins made by normal cells. The results are analyzed in relation to the use of this suspension cell culture system for isolating conditional lethal mutants of plant cells.     

Cell-cycle differences of HL-60 leukemia cells fractionated by centrifugal elutriation

HL-60 leukemia cells were fractionated into G1 and S/G2 populations using a rapid centrifugal elutriation technique, and studied for differences between the cell-cycle phases. The G1 fraction was found to contain smaller cells with a sedimentation velocity of 7 mm/h. The S/G2 fraction consisted of larger cells with a sedimentation velocity of 125 mm/h. The latter fraction was found to have a peak level of the enzyme (2'-5')An-binding protein, as compared to the G1 fraction, indicating a possible role for (2'-5')An-binding protein and its products in the growth regulation of these leukemic cells. In addition, cytofluorometric analysis of fractionated HL-60 cells indicates that elutriation is an effective fractionation method, rapidly yielding large numbers of cells for study, without the use of chemical treatments.     

Improved methods for automatic monitoring of contracting heart cells in culture

The present communication describes improved methods for isolating and plating beating heart cells from neonatal rats using collagenase and collagen-coated petri dishes. The amplitude and frequency of contraction are continuously and simultaneously measured under well defined conditions and during prolonged periods of time with a highly sensitive and thermostated instrument. Additions, e.g. drugs and toxic agents, are made through an accessory pump system that involves extensive dilution of the added compound with medium; aliquots of medium can be withdrawn for estimation of metabolites. The system described is reliable and relatively inexpensive and allows a more extensive use of isolated heart cells, especially in studies of heart functions where small changes in amplitude and frequency of beating during prolonged periods of time are important.     

Development of a topographically organized auditory network in slice culture is calcium dependent

Inhibitory and excitatory connections of remarkably precise topographic order are characteristic features of the mammalian auditory system, particularly within the superior olivary complex (SOC). Little is known about the requirements for the correct development of these specific connections. Previous in vivo experiments have demonstrated a high expression of calcium-binding proteins in this system during development, pointing to the need for precise calcium regulation. Here, we have employed an organotypic slice culture from the above neuronal network and analyzed the requirements for the maintenance and development of this system in vitro. When slices from neonatal rats were incubated in standard culture medium for up to 7 days, we found no organotypic features. Only if 25 mM KCl was added to the culture medium, the cytoarchitecture of the nuclei, the neuronal morphology, and the specificity and topography of internuclear connections were indistinguishable from that in vivo. The addition of calcium channel blockers (MgCl₂ and nifedipine) to the high-KCl medium reduced organotypicity drastically, indicating that a depolarization-induced increase of intracellular calcium is indispensable. Furthermore, the temporal course of the expression of the calcium-binding protein parvalbumin in culture under high KCl mimics that in vivo, demonstrating developmental processes during incubation. The need for calcium influx into neurons of this auditory network in vitro (which is not seen in other slice culture systems) strengthens the hypothesis that an optimal calcium concentration is exceptionally important in auditory neurons. The effect of KCl in the slice cultures may substitute for input activity regulating intracellular calcium in auditory neurons in vivo. © 1998 John Wiley & Sons, Inc. J Neurobiol 34: 97–112, 1998     

Interferometric studies of endothelial cells in primary culture

Summary A population of endothelial cells growth from Xenopus laevis tadpole hearts was investigated by microinterferometry. The resulting interferograms were evaluated by an automatic image analyzer. The mean values of dry mass were 778±340 pg (10^–15 g) for whole cells, 648±309 pg for cytoplasm, 116±45 pg for nuclei, and 19±10 pg for nucleoli. Two subpopulations of cells were identified, an actively growing one and a less active one. The density (dry mass per m²) of the nuclei and nucleoli of less active cells was greater than that of the nuclei and nucleoli of actively growing cells. In addition, the inactive cells were always large and possessed a considerable amount of cytoplasm. The entrance of cells into S-phase could not be detected by microinterferometry; and no differences were apparent between cells possessing one nucleolus and those containing two nucleoli. The values obtained in these amphibian cells were compared with those derived from mammalian cells.     

Response of epithelial and mesenchymal cells to culture on basement lamella observed by scanning microscopy

The basement lamella of Xenopus tadpole skin has been viewed in situ by scanning microscopy, then isolated by trypsin treatment and used as a substrate for cell culture. The basal lamina may also be viewed after EDTA treatment. Responses of epithelial and mesenchymal cells to the lamella have been compared. Mesenchymal cells from chick skin and heart ventricle flatten and attach between the plies of the lamella, then infiltrate it. Myoblasts appear to move less readily within the lamella. Embryonic Xenopus skin epithelium spreads over the surface. Isolated chick skin epithelial cells first begin to spread, then round up and eventually attach to each other in clusters which form a flat basal surface above the lamella. Thus epithelial and mesenchymal cells cultured on this isolated extracellular material mimic aspects of normal tissue organization.     

Cell-cycle regulation of insulin-stimulated tyrosine aminotransferase activity in rat hepatoma cells

Amongst the proteins that are subjected to variation during the cell division cycle few are under hormonal regulation. The variation in amount of tyrosine aminotransferase (TAT) in the hepatic tissue is under the control of glucagon, glucocorticoids and insulin. It has been reported that the inducibility of TAT activity by dexamethasone in rat hepatoma (HTC) is limited to the late G1 and the S portions of the cell cycle. Evidence is presented in this report that in the rat hepatoma Fao, insulin (which has the capability to promote both cell growth and hormonal effects via its own receptors) modulates the TAT activity during the cell cycle. The maximal insulin-stimulated induction of TAT activity was observed at the end of the G1 phase and then decreased as cells progressed through their mitotic cycle. The number of insulin binding sites per cell was decreased by only 30% during the same period of time. Furthermore, the extent of receptor autophosphorylation decreased in the same proportion, suggesting that insulin receptors remained functional through the whole cell cycle. In fact, another insulin-stimulated cellular function, neutral amino-acid transport, was not modified as cells progressed into the S phase. Hydroxyurea, which is known to prevent cell progression into the S phase, stabilized the insulin-induced TAT activity at its maximal level for several hours. Reciprocally, removal of hydroxyurea resulted in a concomitant decrease in TAT activity and reinitiation of DNA synthesis.     

Cell-cycle distribution of pancreatic cells from rats with acute pancreatitis induced by bile-pancreatic obstruction

The aim of this study was to analyze, using electron microscopy, the morphological alterations that progressively appear in the pancreas of rats with acute pancreatitis induced by bile-pancreatic obstruction over 48 h. In addition, in order to ascertain the capability of pancreas regeneration at different stages of pancreatitis, the distribution of pancreatic cells throughout the different phases of the cell cycle was also analyzed by flow cytometry using propidium iodide staining. Interstitial edema, macrophage infiltration, vacuolization, and dilatation of endoplasmic reticulum were observed from 1.5 h after obstruction onward. Interestingly, cell cycle studies showed an increased proportion of S-phase cells at early stages of pancreatitis (1.5 h after obstruction), which leads to a significant increase in cells in G2/M phase 12 h after pancreatic obstruction. Histological studies revealed severe alterations in pancreas of rats with obstruction maintained over 48 h which affects the nuclear structure. Intracellular disorganization, apoptosis, and focal necrosis were observed at this stage. Furthermore, flow-cytometric analysis of cell DNA contents showed a significant decrease in the proportion of S and G2/M cells and a significant increase in G0/G1 cells, suggesting an arrest of almost all cells in quiescent states. These results suggest that rat pancreas cells are able to recover during the first 12 h after pancreatic obstruction. However, the gland would lose its ability to regenerate if the obstruction was maintained for longer periods.     

A multiparametric approach to studies of self-organization of globular proteins

This review analyzes the problem of using a multiparametric approach to studies of the process of globular protein folding. The principles of the most widespread contemporary physicochemical methods for studying the structural properties of globular protein molecules are considered. The specific information that can be obtained by using these structural methods is discussed.     

Autoradiographic studies of pyridine nucleotide metabolism in human culture cells

More than 80% of the intracellular pyridine metabolite pool of human culture cells is trapped by OsO₄ fixation. The fixed pyridine metabolites fully exchange with nicotinamide and nicotinic acid but not with nicotinamide adenine dinucleotide. Yet, chromatography of the exchanged compounds reveals that NAD and NADP constitute more than 95%. of the fixed material. Although the mechanism of OsO₄ fixation is not fully understood, such fixation has permitted the autoradiographic detection of intracellular pyridine metabolites. Cells of the human cell line, D98/AH2, synthesize pyridine nucleotides during all phases of the cell cycle at rates which do not vary by more than six-fold. There is no difference in the apparent concentration of pyridine metabolites between nucleus and cytoplasm after ten minute or three day pulses with ³H-nicotinic acid. The ³H-labeled pyridine ring is lost from D98/AH2 cells upon transfer to unlabeled medium. In general, the rate of loss is uniform among cells in the population. However, in a small proportion of cells there is little or no loss. Non-dividing cells lose the pyridine ring at approximately the same rate as dividing cells, yet the intracellular concentration of pyridine metabolites is 50% greater in non-dividing cells.     

Application of high-pressure liquid chromatography to studies of collagen production by isolated cells in culture

Techniques for assessing collagen production by cells in culture are usually based on evaluation of uptake of radiolabeled proline into collagen. Although simple in theory, this approach is often flawed because of uncertainties concerning the specific activity of labeled proline in the precursor pool for collagen synthesis. An alternative approach is to assess collagen production directly by measuring hydroxyproline in proteins secreted by cultured cells, although this has been difficult, due to the insensitivity of the methods available. Here we apply high-pressure liquid chromatography using reverse-phase elution of 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole derivatives of hydroxyproline to measure collagen production by fibroblasts. The method is easy to perform and allows quantitation of hydroxyproline down to 5 pmol, making it applicable to fibroblasts in 12-well culture plates. Collagen production was shown to be constant over a period of 24 h, with a mean rate of 391 +/- 18 (SE n = 14) ng collagen/10(6) cells/h. Similar values were obtained using thin-layer chromatography and an enzyme-linked immunosorbent assay for type I collagen, but these techniques were judged to be less convenient and required additional assumptions compared with the technique described here in full.     

Amphibian cells in culture. I. Nutritional studies.

Nutritional requirements of amphibian cells in culture were studied for the purpose of modifying a minimal medium in which frog cells could proliferate and which could be used for obtaining drug-resistant and auxotrophic variants. The serum, purine, CO2, and amino acid requirements for ICR 2A (a Rana pipiens haploid cell strain) have been investigated employing two different media: L-15, a nonbicarbonate, amino acid-buffered medium and Eagle's MEM, a bicarbonate-buffered medium. In this paper we present evidence to support the following conclusions: (1) With L-15 as the base medium, 10% fetal calf serum (FCS) supports optimal cell growth during exponential phase. Calf serum, whole, dialyzed, or heat-inactivated, cannot substitute for FCS and, in fact, is inhibitory. (2) Purines are required by ICR 2A cells only if grown in a nonbicarbonate-buffered medium, since the cells under these conditions cannot produce enough endogenous CO2 to support de novo purine synthesis. (3) In addition to the amino acids considered essential for mammalian cells in culture, ICR 2A cells depend upon exogenous asparagine. Glutamine and/or aspartic acid cannot replace the asparagine requirement. However, ICR 2A cells do utilized exogenous glutamine as an oxidative substrate.     

Metabolic and temporal studies on pancreatic exocrine cells in culture

Summary An approach is described whereby cells with definitive markers are followed from their source through dissociation and fractionation, then during long-term maintenance in vitro. Such sequential studies should enable investigators to define factors regulating proliferation and function of specific cells since ambiguity concerning identity is readily avoided.Pancreatic cells of guinea pigs were isolated by enzymic dissociation, and exocrine cells were enriched by centrifugation with solutions of serum albumin. Resulting populations consisting of up to 95% exocrine cells were then incubated with gyration to produce aggregates, and these were seeded to standard culture plates for further study. Colonial aggregates of exocrine epithelia develop in culture and can be maintained for 20–30 days. The cells exhibit changes with time that are qualitatively similar to those known to occur during serial cultivation of diploid fibroblastlike cells from human and other species. The uptake of tritiated thymidine decreases with maintenance time. Autoradiographic examination indicates that this is due to a reduction in the number of epithelial cells incorporating the isotope. Cell diameters increase from an average of 21 m at day 0 to 44 m by day 26, and a marked increase in heterogeneity of this parameter is also evident. Cellular DNA and protein accumulate during the same interval. Incorporation of tritiated leucine during 24-h exposures increases until about the 10th day in vitro and remains relatively constant for at least 2 weeks thereafter.The data are consistent with the hypothesis that exocrine pancreatic cells like other diploid cells in culture, progress to terminal differentiation under the culture conditions employed. The role of physical, nutritional, and humoral evironmental factors on this process will be the subject of future reports.Supported in part by National Cancer Institute Contracts NO1-CP-43231 and NO1-CP-65751     

Cell-cycle inhibition and apoptosis induced by curcumin and cisplatin or oxaliplatin in human ovarian carcinoma cells

Alteration of appropriate cell‐cycle progression and of closely related apoptotic process is a basic feature of tumour cells, and development of new tumour‐targeted agents focus on apoptosis, either during cell‐cycle arrest or following premature cell‐cycle checkpoint exit. Increasingly, epidemiological and experimental studies suggest that curcumin protects against cancer, not only because of its well‐known antioxidant properties, but also because it modulates intracellular signalling, which is related to cell proliferation and apoptosis. Cisplatin and oxaliplatin are first‐line drugs in treatment of many types of epithelial cancer and their combination with other cytostatics are under investigation to limit their side effects and resistance to them. Objectives: The aim of this study was to evaluate effects of a combined treatment using curcumin with cisplatin or with oxaliplatin, in a human ovarian cancer cell line (2008) and in its cisplatin‐resistant variant (C13). Results: Curcumin per se caused concentration‐dependent (0.1–100 µm ) and time‐persistent (24–72 h) reduction in cell proliferation, as well as altered cell cycle parameters and induced apoptosis, in both cell lines. When carcinoma cells were simultaneously exposed to curcumin and to cisplatin or oxaliplatin (at concentrations lower than IC₅₀) cell viability was reduced more than with single‐drug treatment. Moreover, dose and time related effects of curcumin, when combined with platinum drugs, were linked to consistent reduction in cell cycling and increased apoptosis, in comparison with single‐drug treatment. These effects were significant both in wild type and in cisplatin‐resistant cells, indicating that curcumin was also able to increase sensitivity of resistant ovarian cancer cells to cisplatin. Conclusions: The data suggests that curcumin is an interesting natural compound capable of limiting cell proliferation and possibly increasing clinical impact of platinum drugs, in ovarian cancer patients.