Tetraploid cycle in ageing solid tumours

When the mouse mammary adenocarcinoma 755 (Ca-755) reaches the plateau phase of growth, non-cycling cells with a G2-DNA content can be observed. They may belong to the diploid cell cycle but they could also be blocked in G0 or G1 of a tetraploid cycle. This hypothesis was tested in three ways: (1) non-cycling G2 nuclei were stained with a combination of Feulgen and naphthol yellow which revealed two populations, one with a low protein content and the other with a high protein content--the latter may represent nuclei ready to begin a new phase of DNA synthesis; (2) Feulgen staining and autoradiography were performed after tritiated thymidine had been administered to mice continuously: this showed that there were cells synthesizing DNA with a DNA index above 2; and (3) cells having 80 chromosomes, corresponding to the tetraploid cycle, were found almost exclusively in the plateau phase tumours. On the other hand, the use of texture and DNA parameters of the Feulgen stained nuclei showed that they were concentrated in a diploid cycle for tumours in the exponential phase of growth and were divided between a diploid and tetraploid cycle for 'plateau' cells. Neither the cause for, nor the role played by, polyploid cells is known.     

Flow cytometric study of cultured mammalian cells.

Flow cytometry provides a rapid, sensitive and accurate analytical means to monitor hybridoma cell cultures. The use of flow cytometry has enabled us to study the changes in DNA, RNA, protein, IgG, mitochondrial activity and cell size that take place during the growth cycle of batch culture. The temporal changes in the levels of these analytes and their heterogeneity have been related to the growth/death kinetics. The maximum proportion of S-cells was reached early in the growth phase while a population of low fluorescence cells with lower polidy than G1, dead cells and fragmented nuclei emerged during the death phase. Supplementation with amino acids during the exponential phase prolonged the growth cycle by enhancing cell proliferation. The fraction of S/G2 cells was much reduced by a reduction in serum concentration but was maintained during the prolonged non-proliferating "stationary" phase. The magnitude of Rhodamine 123 staining showed a consistent and general decrease during late exponential and decline phases. This trend was accompanied by an increase in the fraction of the Propidium Iodide-stained population which reflected the deteriorating metabolic and membrane integrity. Decrease in mean fluorescence intensity for DNA, RNA, protein and intracellular IgG was noted at the decline phase. Intracellular immunofluorescence was a more reliable indicator of antibody productivity than surface immunofluorescence.     

Correlation between cell cycle duration and RNA content.

The metachromatic fluorochrome acridine orange was used to differentially stain DNA and RNA in Chinese hamster ovary (CHO) cells and in mitogen-stimulated human lymphocytes during their progression through the cell cycle. Green and red fluorescence of individual cells, representing cellular DNA and RNA, respectively, was measured by flow cytometry. CHO cells were synchronized by selective detachment at mitosis. Their rate of progression through G1 and subsequently through S phase correlated with the content of stainable RNA. The mean duration of the G1 phase was 5.2 hours for cells with high RNA content (highest 25 percentile population) and 8.1 hours for cells with low RNA (lowest 25 percentile). The duration of S phase was 5.9 and 7.5 hours for high- and low-RNA, 25 percentile subpopulations, respectively. Lymphocytes synchronized at the G1/S boundary by hydroxyurea or 5-fluorodeoxyuridine showed extremely high intercellular variation with respect to content of stainable RNA. After release from the block they traversed S phase at rates linearly proportional to the content of stainable RNA. The duration of S phase was five hours for cells with high RNA-, six to nine hours for cells with moderate RNA- and up to 27 hours for cells with minimal RNA-content. The data suggest that the rate of progression through the cell cycle of individual cells within a population may be correlated with the number of ribosomes per cell.     

Expression of proliferation associated antigens in the cell cycle of synchronized mammalian cells.

Flow cytometric bivariate analysis was used to investigate the expression of PCNA, p120 and p145 during the cell cycle of a mammalian cell line (CHO-K1). Initially, aliquots of cells in exponential and plateau (G0) phase were analyzed for proliferation associated antigen expression. Expression of PCNA and p145 during G0 was markedly depressed (less than 12% positive) while 54% of the G0 cells stained positive for p120. The fluorescent intensity (mean channel fluorescence) of these G0 positive p120 cells, however, was only slightly above the mean channel fluorescence (MCF) of cells stained with a negative isotype control. In asynchronous cultures, all three antigens were expressed in greater than 70% of the cells, with PCNA staining being greater than 95%. Cells were then synchronized using mitotic selection (mitotic index of 97%) and antigen levels were measured as cells progressed synchronously through the cell cycle. From DNA analysis histograms, it appeared that the degree of synchrony was approximately 90% throughout the remainder of the cell cycle. The bivariate DNA/PCNA, DNA/p120, and DNA/p145 histograms for mitotic cells indicated that both p120 and p145 expression were elevated (percent positive and MCF) while PCNA levels were near controls (MCF). In early G1, all three markers were depressed (less than 12% positive); however PCNA levels rose precipitously in mid-G1 (greater than 50% positive). In late G1 to early S, p145 levels increased concomitantly with increases in p120. All three antigens were elevated throughout S phase and began to decline as cells moved from G2/M to G1 of the next cell cycle with p145 expression decreasing first. This report indicates that all three proliferation associated antigens studied are differentially expressed in the cell cycle and therefore may be useful in detecting and assessing the proliferation state.     

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.     

Concentration-dependent effects of potassium dichromate on the cell cycle

Hexavalent chromium is found to be a strong mutagen, and it also is a potential carcinogen in man. DNA flow cytometry, growth measurements, and determinations of mitotic index show that 1-2 microM K2Cr2O7 produces a prolongation of the G2 phase of the cell cycle in NHIK 3025 cells. By increasing the chromate concentrations (greater than 2 microM K2Cr2O7) the cells are also arrested in G2 phase. We have found, using synchronized cells and measuring cell cycle time, that the most chromate-sensitive part of the cell cycle is S phase. This phase is also somewhat prolonged, and the cells became arrested in early S phase at high toxic K2Cr2O7 concentrations (8 microM). Our results thus indicate that K2Cr2O7 has an effect within S phase--maybe on DNA/RNA synthesis--and also interferes with processes necessary for progression through the G2 phase.     

Molecular Cloning of a Murine cDNA Encoding a Novel Protein, p38-2G4, Which Varies with the Cell Cycle

Proliferating cells express genes active in cell cycle control. The modulation of control genes and factors are required to maintain critical cell cycle activities. We used a set of monoclonal antibodies prepared against DNA-binding proteins from Ehrlich ascites tumor cells in immunofluorescent microscopy to screen for proteins showing cell cycle-specific staining patterns. Here, we report cloning and characterizing of a novel mitogen-inducible gene from murine macrophages that predicts a cell cycle-specifically modulated nuclear protein of 38 kDa, designated p38-2G4. p38-2G4 displayed a speckled pattern of varying fluorescence intensity confined to the nucleus, but sparing the nucleoli. Strongly stained granules were observed between G1 and mid S phase, followed by a less abundant punctated arrangement toward the end of S phase, and negative fluorescence at the S/G2 transition. Thereafter, the nuclear staining reappeared. Additionally, p38-2G4 expression vanished in G0-arrested cells and was restored after release from growth arrest. p38-2G4 conserved in vertebrates by means of immunofluorescence data contains a number of putative phosphorylation sites, a cryptic nuclear localization signal, and an amphipathic helical domain. Our cDNA and its deduced amino acid sequence is related to a Schizosaccharomyces pombe gene encoding a 42-kDa protein that associates with curved DNA, suggesting that we have cloned the murine homologue of the S. pombe gene which defines a novel cell cycle-specifically modified and proliferation-associated nuclear protein in mammals.     

Flow cytometric and biochemical analysis of dose-dependent effects of sodium butyrate on human endometrial adenocarcinoma cells.

Sodium butyrate (SB) treatment was previously shown to produce seven-fold increases in estrogen hormone receptor binding sites of human endometrial adenocarcinoma (IK) cells. Flow cytometric analysis and histone gel electrophoresis were used to examine cell cycle, cell metabolism, and nuclear histone fractions in IK cells treated with different concentrations of SB. SB-treated cells stained with fluorochromes specific for DNA, RNA, or general protein were analyzed by flow cytometry (FCM). Changes in accessibility to three DNA stains and gel electrophoresis were used to analyze rearrangements in chromatin structure. SB caused an accumulation of cells in the G1 phase and inhibited DNA synthesis, but not cellular levels of RNA and protein. Hoechst accessibility to A-T rich regions on DNA was dramatically increased after removal of SB. H1 histones were dephosphorylated and core histones were acetylated during SB-treatment. Information obtained in these studies may be useful for correlating cellular and biochemical events with SB-induced increases in nuclear steroid hormone binding sites.     

Simultaneous detection of cyclin B1, p105, and DNA content provides complete cell cycle phase fraction analysis of cells that endoreduplicate

BACKGROUND: DNA analysis of endoreduplicating cells is difficult because of the overlap between stem-line G2 + M cells and 4C G1 cells. Simultaneous flow cytometry of DNA and cyclin B1 analytically separates these populations. The objective here was to develop simultaneous flow cytometry of DNA, cyclin B1, and p105 (highly expressed in mitosis) for improved, complete cell cycle phase fraction analysis of endoreduplicating cell populations. METHODS: Monoclonal antibody, GNS-1, reactive with human cyclin B1, was conjugated with fluorescein at three different fluorochrome-to-protein (F/P) ratios and tested for optimal sensitivity in a flow cytometric assay. A formaldehyde-methanol fixation procedure was optimized for retention of p105 within mitotic cells by analytic titration of formaldehyde. p105 was stained indirectly with Cy5-conjugated secondary antibody, followed by GNS-1, and DNA was stained with Hoechst 33342. The specificity of p105 in this assay was tested by comparison of manual and flow cytometric mitotic indices and by sorting and microscopic inspection. RESULTS: F/P 4.1 provided optimal fluorescein labeling of GNS-1. Formaldehyde (0.5%), followed by methanol permeabilization, fixed cells sufficiently to quantify stem-line and endoreduplicated G1, S, G2, and M phase fractions. Kinetic measurements of these fractions for both populations were demonstrated. CONCLUSIONS: The fluorochrome-to-protein ratio is important and can be optimized objectively for these assays. A permeabilization-sensitive antigen (p105), previously requiring formaldehyde/detergent-fixed cell preparations, was shown to work equally well with formaldehyde/ methanol fixation. Three-laser, two-parameter intracellular antigen analysis can be successfully coupled with DNA content analysis. Cell cycle kinetic analysis of endoreduplicating populations should be improved.     

A new method for rapid and sensitive detection of bromodeoxyuridine in DNA-replicating cells

A new flow cytometric technique, involving differential fluorescence analysis of two DNA-binding fluorochromes, was used to quantify cellular incorporation of the base analog, bromodeoxyuridine (BrdU), into DNA over short time periods. During analysis of stained cells, the blue fluorescence signal of Hoechst 33342, which is quenched by BrdU-substituted DNA, was subtracted, on a cell by cell basis, from the green-yellow fluorescence signal of mithramycin, which remained stoichiometric to cellular DNA content. Bivariate contour profiles obtained for CHO cells pulse-labeled for 30 min showed that fluorescence quenching of Hoechst 33342 in BrdU-labeled, S phase cells produced fluorescence difference signals that were significantly greater than the difference signals from G1 and G2 + M phase cells. Analysis of L1210 cells demonstrated that the amount of BrdU detected was proportional to the length of the labeling period. The novel technique is simple, rapid, and mild; it produces minimal cell loss and does not significantly affect cellular moieties such as DNA, chromatin, or RNA.     

The alkaline hydrolysis of nucleic acid for removal of RNA associated fluorescence in phenantridium related flow through cytofluorometry

Summary Flow through microfluorometry of phenantridium and fluoresceinisothiocyanate stained HeLa cells showed the absence of extranuclear RNA related fluorescence after prolonged hydrolysis of cells in ethanolic barium hydroxide. DNA distribution were as good as in RNAse treated samples. Distribution pattern of cellular protein/DNA ratios yielded greater resolution power than those after RNAse digestion. The cellular protein content has not been affected. The ethanolic hydrolysis has the advantage to be of less expense and to allow cell conservations for further measurements with other well preserving fixatives. Thus, application of glutaraldehyde has been proved to be valuable.     

The alkaline hydrolysis of nucleic acid for removal of RNA associated fluorescence in phenantridium related flow through cytofluorometry.

Flow through microfluorometry of phenantridium and fluoresceinisothiocyanate stained HeLa cells showed the absence of extranuclear RNA related fluorescence after prolonged hydrolysis of cells in ethanolic barium hydroxide. DNA distribution were as good as in RNAse treated samples. Distribution pattern of cellular protein/DNA ratios yielded greater resolution power than those after RNAse digestion. The cellular protein content has not been affected. The ethanolic hydrolysis has the advantage to be of less expense and to allow cell conservations for further measurements with other well preserving fixatives. Thus, application of glutaraldehyde has been proved to be valuable.     

Changes in the DNA,RNA and Protein Contents During the Root-Tip Cell Differentiation of Triticum aestivum

One to two cm long root tips of Triticum aestivum L., after three days' germination at 25 ℃, each were cut into three regions--the meristem region, elongation region and mature region. The cells in different regions were stained with Hochest 33258, Pymnin G and FITC respectively. Nuclear DNA was measured by micmfluorometry with VIDAS digital image analysis system. The relative contents of RNA and protein in the cells were measured with a MPV-Ⅲ microspectrofluorometer. It was shown that the nuclear DNA content increased during root tip cell differentiation, being maximum in the mature region. The relative content of RNA was maximum in the meristem region, but decreased continuously during the growth of tissue. The relative content of protein was maximum in the elongation region, but minimum in the meristem region. The relationships among DNA, RNA, protein and cell differentiation were discussed.     

Changes in cell cycle and RNA content in cultured cancer cells treated with cis-diamminedichloroplatinum (II)

Recent reports have shown that CDDP interacts with RNA and protein as well as DNA. We studied the alteration of cell cycle, cellular RNA content and the effect of nucleic acid metabolism on cultured cancer cells after treatment with CDDP by flow cytometry and 3H incorporation assay. The alteration of cell cycle was found to be accumulation of cells in after delay S phase in cytostatic concentrations, CDDP inhibited 3H-TdR uptake markedly at this time and 3H-UR uptake earlier. Increase in RNA content accompanied accumulation of cells in G2M phase. This increase was not a specific phenomenon caused by CDDP, because increase in RNA content was also induced by other inhibitors of DNA synthesis. It is more likely that the direct alteration of cell cycle and cellular RNA content due to action of DNA-combined CDDP rather than that of RNA-combined CDDP.     

小麦根尖细胞分化过程中DNA,RNA和蛋白质含量变化的研究

小麦(Triticum aestivum L.)种子在25℃条件下萌发3d,根生长至1～2cm长时,于双筒解剖镜下严格切取根分生区、伸长区和成熟区。用专一性荧光染料Hochest33258、Pyronin G和FITC分别染细胞核DNA、RNA和蛋白质,并用自动图像分析技术和细胞荧光测定术分别测定三个区中各125个细胞核DNA的相对含量和各100个细胞中RNA和蛋白质的相对含量。核DNA相对含量随着根尖细胞分化的进程,DNA含量递增,成熟区细胞中含量最高。RNA的相对含量则与之相反,在分生区细胞中含量最高,成熟区细胞中含量最低。蛋白质的相对含量则在伸长区细胞中最高,分生区细胞中最低。讨论了根尖细胞分化过程中DNA、RNA和蛋白质三者之间变化的一些内在联系。     

Relationship between changes of the steroid receptor and synchronization in human endometrial adenocarcinoma cells in vitro

It has been reported that the response of target cells to steroid hormone (SH) stimulation may depend on their position in the cell cycle. The DNA and RNA contents of malignant cells of the endometrium cultured in vitro were measured using flow cytometry (FCM). We also measured estrogen receptor (ER) and progesterone receptor (PR) levels of cells at different positions in the cell cycle. The G1 and S phases of the cell cycle were investigated using cells synchronized by sodium n-butyrate (G1 block), methotrexate (S block), and excess thymidine (S block). For DNA measurements, the cells were stained with propidium iodide following RNase treatment. For RNA measurements (double-stranded RNA) the cells were treated with DNase. We found that S phase synchronization by methotrexate was 136.2% of control (100%). Using the excess thymidine block and release procedure, the S phase fraction was 185.1% of control. G1 phase synchronization by sodium n-butyrate was 134% of control. The estrogen receptor level in G1 phase synchronized cells increased to 5.94 fmol/micrograms DNA in the cytosol and 12.35 fmol/micrograms DNA in the nuclear fraction. These levels represent a sevenfold total increase over that of the control estrogen receptor level. Cells in S phase showed no significant increase in estrogen receptor levels over control cells. Based on this study, the functional increase of the steroid receptor was most significant in the G1 phase.     

Thymidine as a synchronizing agent. I. Nucleic acid and protein formation in synchronous HeLa cultures treated with excess thymidine

Synchronous cultures of HeLa cells obtained by selective detachment of mitoses were treated with high concentrations of thymidine. The inhibitor was added soon after completion of cell division and rates of cell enlargement and accumulation of DNA, RNA and protein were compared for untreated and thymidine-treated cultures at various points of the cell cycle. It was found that concentrations of thymidine which in randomly growing cultures inhibit the rate of cell division by more than 90% allowed a considerable degree of DNA synthesis and did not affect the rate of accumulation of RNA and protein, when applied to cells in the G1 phase of synchronous culture. Treated and untreated cells enlarged at the same rate throughout their life cycle. The results show that concentrations of thymidine commonly employed to produce cell synchrony do not arrest the cells at the G1-S boundary, but allow slow progress through S in respect to DNA synthesis, and near-normal progress towards G2 as regards RNA and protein accumulation and cell enlargement.     

用双参数流式细胞光度术(FCM)研究阿克拉霉素对L_(1210)白血病细胞周期的影响

本文用双参数FCM技术,对同一个细胞的DNA和RNA含量进行相关测量,比较了ACM B对小鼠L_(1210)白血病细胞周期和RNA含量的影响.结果发现在一次给药后8小时可导致早、中期S的积累,并抑制S期细胞的DNA合成;到24小时DNA合成恢复正常,并进入G_2期,但由于G_2期细胞进入M期受阻,造成G_2期细胞的积累,这时被阻断在G_2期的细胞RNA含量显著增加,形成正不平衡生长,而给药剂量较大的实验组(1/1.5LD_(50))S期细胞的RNA含量不随着DNA含量的增加而增加,形成负不平衡生长,ACM A和ACM B对体内Li_(210)细胞周期作用相同.     

G2/M cell cycle arrest and induction of apoptosis by a stilbenoid, 3,4,5-trimethoxy-4'-bromo-cis-stilbene, in human lung cancer cells

Stilbenoids, including resveratrol (3,5,4'-trihydroxy-trans-stilbene) which is a naturally occurring phytoalexin abundant in grapes and several plants, have been shown to be active in inhibiting proliferation and inducing apoptosis in human cancer cell lines. Using resveratrol as the prototype, we have synthesized various analogs and evaluated their growth inhibitory effects in cultured human cancer cells. In the present study, we show that one of the stilbenoids, 3,4,5-trimethoxy-4'-bromo-cis-stilbene (BCS), was more effective than its corresponding trans-isomer and resveratrol on the inhibition of cancer cell growth. Prompted by the strong growth inhibitory activity of BCS (IC50; 0.03 microM) compared to its trans-isomer (IC50; 6.36 microM) and resveratrol (IC50; 33.0 microM) in cultured human lung cancer cells (A549), we investigated its mechanism of action. BCS induced arrest at the G2/M phase cell cycle in the early time and subsequently increased in the sub-G1 phase DNA contents in a time-dependent manner, indicating induction of apoptosis. Morphological observation with round-up shape and DNA fragmentation was also revealed the apoptotic phenomena. BCS treatment elevated the expression levels of the pro-apoptotic protein p53, the cyclin-dependent kinase inhibitor p21, and the release of cytochrome c in the cytosol. The down-regulation of checkpoint protein cyclin B1 by BCS was well correlated with the cell cycle arrest at G2/M. These data suggest the potential of BCS to serve as a cancer chemotherapeutic or chemopreventive agent by virtue of arresting the cell cycle and induction of apoptosis of human lung cancer cells.