Measurement of c-myc protein content and cell cycle kinetics of normal and spontaneously transformed murine mastocytes by bivariate flow cytometry

Abstract. Progressive in vitro culturing of interleukin-3 (IL-3) dependent normal murine mastocytes (PB-3) resulted in a variant cell line (PB-1) able to grow without exogenous IL-3 and which was tumorogenic in syngenic mice. Bivariate flow cytometry was used to evaluate the c-myc protein and DNA content of PB-3 and PB-1 cells. The c-myc protein was detected by specific monoclonal antibodies. Kinetic characteristics of PB-3 and PB-1 cell lines, namely, the duration of the G¹, S and G₂+ M cell cycle phases were also evaluated using the bromodeoxyuridine (BrdU) pulse-chase method and BrdU/DNA flow cytometry. Levels of c-myc protein in PB-1 cells were about twofold higher than those of PB-3 cells in all cell cycle phases. Mean duration of the cell cycle ( T _c) was 15-3 h for PB-3 cells and 12-4 h for PB-1 cells. Shortening in T _c for the transformed cells was due to a decrease of nearly 30% in mean duration of the G ₁ phase (from 8 h to 5.7 h). No significant differences were found in the duration of the S and G₂+ M phases. These results indicate that acquired IL-3 independency in vitro and tumorogenicity of PB-1 cells were accompanied by a doubling of c-myc protein level and by a parallel shortening, or bypass, of the regulatory events within the G¹ phase of the cell cycle.     

Continuous bromodeoxyuridine labeling and bivariate ethidium bromide/Hoechst flow cytometry in cell kinetics

Most techniques of flow cytometric cell cycle analysis are not capable of distinguishing the number of rounds of DNA synthesis that a cell has undergone since the start of an experiment. Continuous labeling with 5-bromodeoxyuridine (BrdUrd) offers such a potential. We illustrate here that the bivariate analysis of non-BrdUrd-quenched ethidium bromide vs. BrdUrd-quenched Hoechst 33258 fluorescence offers a high degree of resolution that enhances the analytical power of the technique, and that this approach can be applied to the analysis of a broad range of human and murine primary cells and established cell lines.     

Measuring cell cycle progression kinetics with metabolic labeling and flow cytometry

Precise control of the initiation and subsequent progression through the various phases of the cell cycle are of paramount importance in proliferating cells. Cell cycle division is an integral part of growth and reproduction and deregulation of key cell cycle components have been implicated in the precipitating events of carcinogenesis. Molecular agents in anti-cancer therapies frequently target biological pathways responsible for the regulation and coordination of cell cycle division. Although cell cycle kinetics tend to vary according to cell type, the distribution of cells amongst the four stages of the cell cycle is rather consistent within a particular cell line due to the consistent pattern of mitogen and growth factor expression. Genotoxic events and other cellular stressors can result in a temporary block of cell cycle progression, resulting in arrest or a temporary pause in a particular cell cycle phase to allow for instigation of the appropriate response mechanism. The ability to experimentally observe the behavior of a cell population with reference to their cell cycle progression stage is an important advance in cell biology. Common procedures such as mitotic shake off, differential centrifugation or flow cytometry-based sorting are used to isolate cells at specific stages of the cell cycle. These fractionated, cell cycle phase-enriched populations are then subjected to experimental treatments. Yield, purity and viability of the separated fractions can often be compromised using these physical separation methods. As well, the time lapse between separation of the cell populations and the start of experimental treatment, whereby the fractionated cells can progress from the selected cell cycle stage, can pose significant challenges in the successful implementation and interpretation of these experiments. Other approaches to study cell cycle stages include the use of chemicals to synchronize cells. Treatment of cells with chemical inhibitors of key metabolic processes for each cell cycle stage are useful in blocking the progression of the cell cycle to the next stage. For example, the ribonucleotide reductase inhibitor hydroxyurea halts cells at the G1/S juncture by limiting the supply of deoxynucleotides, the building blocks of DNA. Other notable chemicals include treatment with aphidicolin, a polymerase alpha inhibitor for G1 arrest, treatment with colchicine and nocodazole, both of which interfere with mitotic spindle formation to halt cells in M phase and finally, treatment with the DNA chain terminator 5-fluorodeoxyridine to initiate S phase arrest. Treatment with these chemicals is an effective means of synchronizing an entire population of cells at a particular phase. With removal of the chemical, cells rejoin the cell cycle in unison. Treatment of the test agent following release from the cell cycle blocking chemical ensures that the drug response elicited is from a uniform, cell cycle stage-specific population. However, since many of the chemical synchronizers are known genotoxic compounds, teasing apart the participation of various response pathways (to the synchronizers vs. the test agents) is challenging. Here we describe a metabolic labeling method for following a subpopulation of actively cycling cells through their progression from the DNA replication phase, through to the division and separation of their daughter cells. Coupled with flow cytometry quantification, this protocol enables for measurement of kinetic progression of the cell cycle in the absence of either mechanically- or chemically- induced cellular stresses commonly associated with other cell cycle synchronization methodologies. In the following sections we will discuss the methodology, as well as some of its applications in biomedical research.     

Quantitative description of cell cycle kinetics under chemotherapy utilizing flow cytometry.

A discrete time cell cycle kinetics model is developed to account for the effects of cytotoxic chemotherapy, particularly including the existence of cells destined to die. A model structure is determined from related experiments, leaving key parameter values undetermined. These values are found by determining the best least squares fit of the predicted to the observed DNA distribution data at a series of time intervals. The numerical methods include separable least squares, linear inequality constrained least squares and the Gauss--Newton method. This approach is applied to an experiment in which the Ehrlich ascites tumour was given a single dose of bleomycin. The results include several different parameters, including the age response function and a time series of cell age and DNA distributions, which can be used as a basis for further treatment.     

DNA measurement and cell cycle analysis by flow cytometry

Measurement of cellular DNA content and the analysis of the cell cycle can be performed by flow cytometry. Protocols for DNA measurement have been developed including Bivariate cytokeratin/DNA analysis, Bivariate BrdU/DNA analysis, and multiparameter flow cytometry measurement of cellular DNA content. This review summarises the methods for measurement of cellular DNA and analysis of the cell cycle and discusses the commercial software available for these purposes.     

Simultaneous quantification of c-myc oncoprotein, total cellular protein, and DNA content using multiparameter flow cytometry

Variations in total cellular protein content can confound interpretation of the significance of modulations of specific cellular proteins. In an effort to overcome this problem, a technique is described for the simultaneous measurement of a specific cellular protein, total cellular protein, and DNA content. The method utilizes dual-laser (uv and 488 nm) excitation and three fluorescent dyes: FITC, SR101, and DAPI. FITC-labelled antibody coupled with indirect immunofluorescence was used to quantify the c-myc oncoprotein, whereas SR101 and DAPI were used to measure total cellular protein and cellular DNA, respectively. Flow cytometric measurements of c-myc oncoprotein were compared to densitometric readings of p64c-myc. SR101 protein determinations were compared to those obtained by the Lowry technique. Results indicated that flow cytometric measurements correlated well with those obtained by the biochemical methods. The usefulness of the technique was further examined following treatment of exponentially growing HL-60 cells with 2.5 micrograms/ml cycloheximide for 0 to 12 h. Cycloheximide treatment was found to cause a significant decrease in c-myc oncoprotein content within 2 h (P less than 0.05), a relative increase in the proportion of G0/G1 cells and a modest decrease in total cellular protein. This technique appears to provide a rapid, quantitative approach, useful for investigating alterations in cellular growth balance occurring with cell differentiation, neoplastic transformation, or cell treatment with radiation or cytostatic drugs.     

Differences in growth factor sensitivity between primary and transformed murine cell cultures revealed by BrdU/Hoechst flow cytometry

Spontaneous cell transformation is a common feature of all murine cell cultures grown in vitro for extended periods of time. During early passages, these cultures show either progressively reduced growth or complete cessation of growth; after such a 'crisis' they display increasing growth rates and unlimited lifespan. Here we use a novel bromodeoxyuridine/Hoechst flow-cytometric technique to examine the growth response of diploid and transformed cells of the murine species Micromys minutus under a variety of growth conditions. After spontaneous transformation, growth factor exposure results in increased G0/G1 cell recruitment and higher growth rates than shown by the nontransformed diploid cell fraction. Despite clonal heterogeneity, this difference is seen at all fetal calf serum (FCS) concentrations, although it is most pronounced with low serum. Epidermal growth factor and insulin are shown to act synergistically and promote growth equal to exposures of transformed cultures to 10% FCS. The observed differences in growth factor response between diploid and aneuploid cells could explain the reported lack of a classical growth crisis in growth factor-supplemented media during the spontaneous in vitro transformation of primary cell cultures.     

Simultaneous cell surface phenotype and cell cycle analysis of lymphocytes by flow cytometry

A method for the simultaneous measurement of cell surface components and nucleic acids (DNA and RNA) of human lymphocytes by flow cytometry has been developed, thereby providing a means of analyzing cell surface changes during the various phases of the cell cycle. Unfixed cells were coated with fluorescein-conjugated concanavalin A (F Con A) or surface antigen-specific antibody, fixed sequentially with paraformaldehyde and methanol, treated with specific nucleases, and then stained with propidium iodide. Neither portion of the procedure (cell surface staining, nucleic acid staining) interfered significantly with the other. Cell cycle phases of phytohemagglutinin-stimulated human lymphocytes as determined by this method were comparable with those identified by acridine orange staining. Cell cycle-specific blocking agents were used to additionally demonstrate the specificity of the staining procedure. Simultaneous measurement of cell cycle phase and detection of surface receptors for Con A and T lymphocyte surface determinants was performed with this method.     

DNA content analysis of insect cell lines by flow cytometry

The DNA content of insect cell lines (6 lepidoptera, 1 coleoptera and 1 diptera) was determined by flow cytometry. The DNA profiles of the 8 cell lines tested were different. They were characterized by the presence of several peaks (2 to 7) corresponding to different ploidy levels, by differences in the fluorescence intensity of each peak and by the proportion of cells in each peak. Two cell lines (Cf124 and BmN) were constituted of 2 distinct populations of cells. The DNA profiles of the cell lines were stable among the passages and during the length of time culture. This technique was demonstrated to be useful for the detection of mixed cell lines and nucleopolyhedrovirus cell infection, using Autographa californica MNPV. The flow cytometry gives interesting results on the cell cycle and the ploidy level; it appears as a good tool for insect cell lines characterization. This revised version was published online in July 2006 with corrections to the Cover Date.     

Interrelation between cellular rRNA content and regulation of the cell cycle of normal and transformed mouse cell lines

The relation between cellular rRNA content, as a measure of cell size, and the regulation of the cell cycle has been investigated for swiss 3T3 and the spontaneously transformed swiss 3T6 cell line. It is shown that the characteristic of percent of quiescent cells stimulated into the cell cycle versus cellular rRNA content is basically different for 3T3 and 3T6 cells: 3T3 cells do not enter the cell cycle below a certain threshold of cellular rRNA content, whereas 3T6 cells start proliferation without a substantial increase of rRNA. These data are interpreted as consistent with transformation of 3T6 cells being in essence their uncoupling from the requirement of normal cells of passing over a threshold of cellular rRNA content (cell size) before initiating DNA-replication.     

Simultaneous measurements of DNA and protein content of microorganisms by flow cytometry

Summary The simultaneous measurement of protein and DNA content of yeast on a cell by cell basis is described. A problem associated with partially overlapping fluorescence emission bands of the two fluorochromes is discussed. The rapid flow cytometric assay will be useful to monitor cell growth in industrial fermentation processes.Abbreviations DNA Desoxyribonucleic acid - YEP yeast extract peptone - FITC fluorescein-iso-thiocyanate     

Cell kinetics in mouse epidermis studied by bivariate DNA/bromodeoxyuridine and DNA/keratin flow cytometry.

Hairless mice were injected intraperitoneally with bromodeoxyuridine (Brd-Urd). Basal cells were isolated from epidermis, fixed in 70% ethanol, and prepared for bivariate BrdUrd/DNA flow cytometric (FCM) analysis. Optimum detection of incorporated BrdUrd in DNA was obtained by combining pepsin digestion and acid denaturation. The cell loss was reduced to a minimum by using phosphate-buffered saline containing Ca2+ and Mg2+ to neutralize the acid. The percentage of cells in S phase and the average uptake of BrdUrd per labelled cell in eight consecutive windows throughout the S phase were measured after pulse labelling at intervals during a 24 h period. Furthermore, the cell cycle progression of a pulse-labelled cohort of cells was followed up to 96 h after BrdUrd injection. In general the results from both experiments were in good agreement with previous data from 3H-thymidine labelling studies. The percentage of cells in S phase was highest at night and lowest in the afternoon, whereas the average uptake of BrdUrd per labelled cell showed only minor circadian variations. There were no indications that BrdUrd significantly perturbed normal epidermal growth kinetics. A cell cycle time of about 36 h was observed for the labelled cohort. Indications of heterogeneity in traverse through G1 phase were found, and the existence of slowly cycling or temporarily resting cells in G2 phase was confirmed. There was, however, no evidence of a significant population of temporarily resting cells in the S phase. Bivariate DNA/keratin FCM analysis revealed a high purity of basal cells in the suspensions and indicated that the synthesis of the differentiation-keratin K10 was turned on only in G1 phase and after the last division.     

Kirsten murine sarcoma virus transformed cell lines and a spontaneously transformed rat cell-line produce transforming factors

We have examined culture fluids from a variety of Kirsten murine sarcoma virus (KiMSV) transformed rat and mouse cells for the presence of factors which induce normal Rat-1 cells to assume the transformed phenotype. All KiMSV transformants produced transforming factor (TF). Revertants of KiMSV transformed rat or mouse cells failed to relase TF as did normal rat or mouse cells. Cells transformed by a temperature sensitive mutant of KiMSV produced TF at the permissive temperature but not at the nonpermissive temperature. Further, cells from a spontaneous transformant of Rat-1 cells also produced TF. TF is a small polypeptide which competes for the epidermal growth factor receptor. Its effect upon normal cells is reversible and requires de novo RNA and protein synthesis. Cells treated with TF lose the actin fibers observed in normal fibroblasts, assume a transformed cell morphology, become anchorage independent for growth, grow in low concentrations of serum, grow to a high cell density, and have an increased rate of hexose uptake.     

Effects of temperature on the yeast cell cycle analyzed by flow cytometry

The effects of temperature (in the range 15-36 degrees C) on growth and the nuclear and budding cycle have been studied in populations of the yeast Saccharomyces cerevisiae exponentially growing in batch on yeast nitrogen base (YNB) glucose medium. The maximal rate of exponential growth is achieved at 30 degrees C, and a transition point is apparent at about 20 degrees C. At all tested temperatures DNA replication begins when cells are still unbudded and both the budded period and the postreplicative period have the same temperature dependence. A temperature compensatory mechanism seems to operate in S phase, during which duration remains relatively constant, in the range 21-36 degrees C, while duration of G2+ M phases shows a much more pronounced temperature dependence. The results are discussed in terms of a cell-cycle model for budding yeast.     

Mathematical model analysis of mouse epidermal cell kinetics measured by bivariate DNA/anti-bromodeoxyuridine flow cytometry and continuous [3H]-thymidine labelling

In a previous study the epidermal cell kinetics of hairless mice were investigated with bivariate DNA/anti-bromodeoxyuridine (BrdU) flow cytometry of isolated basal cells after BrdU pulse labelling. The results confirmed our previous observations of two kinetically distinct sub-populations in the G2 phase. However, the results also showed that almost all BrdU-positive cells had left S phase 6-12 h after pulse labelling, contradicting our previous assumption of a distinct, slowly cycling, major sub-population in S phase. The latter study was based on an experiment combining continuous tritiated thymidine [( 3H]TdR) labelling and cell sorting. The purpose of the present study was to use a mathematical model to analyse epidermal cell kinetics by simulating bivariate DNA/BrdU data in order to get more details about the kinetic organization and cell cycle parameter values. We also wanted to re-evaluate our assumption of slowly cycling cells in S phase. The mathematical model shows a good fit to the experimental BrdU data initiated either at 08.00 hours or 20.00 hours. Simultaneously, it was also possible to obtain a good fit to our previous continuous labelling data without including a sub-population of slowly cycling cells in S phase. This was achieved by improving the way in which the continuous [3H]TdR labelling was simulated. The presence of two distinct subpopulations in G2 phase was confirmed and a similar kinetic organization with rapidly and slowly cycling cells in G1 phase is suggested. The sizes of the slowly cycling fractions in G1 and G2 showed the same distinct circadian dependency. The model analysis indicates that a small fraction of BrdU labelled cells (3-5%) was arrested in G2 phase due to BrdU toxicity. This is insignificant compared with the total number of labelled cells and has a negligible effect on the average cell cycle data. However, it comprises 1/3 to 1/2 of the BrdU positive G2 cells after the pulse labelled cells have been distributed among the cell cycle compartments.     

Quantitative determination of the induction of apoptosis in a murine B cell line using flow cytometric bivariate cell cycle analysis.

WEHI-231 cells have been used extensively as a model of tolerance induction in B cells. Recent evidence has shown that anti-IgM treatment of WEHI-231 cells resulted in the induction of apoptosis. In this study, using acridine orange staining and flow cytometric analysis, we demonstrated that apoptotic cells are detected as a distinct population of cells separate from the cells in normal cell cycle progression. The validity of analysis gates was confirmed by cell sorting of the apoptotic population versus normal cells and subsequent gel analysis. Using this technique, we have demonstrated that F(ab')2 anti-mu, A23187, or PMA induced apoptosis in the WEHI-231 cells. The addition of LPS reversed apoptotic induction as seen previously with the WEHI-231 cell line. In contrast, however, PMA did not prevent the induction of apoptosis in anti-mu-treated cells. Additionally, we were interested in determining if the induction of apoptosis was restricted to a specific phase of cell cycle. Since growth inhibition results in most cells arresting in the G1 phase of cell cycle, we wanted to demonstrate apoptosis as a G1-dependent event. This was examined with WEHI-231 cells treated with known cell cycle inhibitors. Interestingly, inhibition of cells in each phase of cycle resulted in the induction of apoptosis. LPS was able to inhibit the induction of apoptosis with each of the cell cycle inhibitors except actinomycin D. Furthermore, we have demonstrated that the WEHI-231 cells contain a Ca(2+)-Mg(2+)-dependent preexisting endonuclease.     

Coordinate analysis of murine immune cell surface markers and intracellular phosphoproteins by flow cytometry

Recently, phosphospecific flow cytometry has emerged as a powerful tool to analyze intracellular signaling events in complex populations of cells because of its ability to simultaneously discriminate cell types based on surface marker expression and measure levels of intracellular phosphoproteins. This has provided novel insights into the cell- and pathway-specific nature of immune signaling. However, we and others have found that the fixation and permeabilization steps necessary for phosphoprotein analysis often negatively affect the resolution of cell types based on surface marker analysis and light scatter characteristics. Therefore, we performed a comprehensive profile of >35 different murine surface marker Abs to understand the effects of fixation and permeabilization on surface Ag staining. Fortuitously, approximately 80% of the Abs tested resolved cell populations of interest, although with decreased separation between positive and negative populations and at very different titers than those used on live cells. The other 20% showed either complete loss of separation between populations or loss of intermediately staining populations. We were able to rescue staining of several of these Ags by performing staining after fixation, but before permeabilization, although with limited fluorophore choices. Scatter characteristics of lymphocytes were well retained, but changed dramatically for monocyte and neutrophil populations. These results compile a comprehensive resource for researchers interested in applying phosphospecific flow cytometry to complex populations of cells while outlining steps necessary to successfully apply new surface marker Abs to this platform.     

Measurement of phagosomal pH of normal and CGD-like human neutrophils by dual fluorescence flow cytometry

BACKGROUND: Phagosomal pH is thought to play an important role in the antimicrobial activity of polymorphonuclear leukocytes (PMNs). In this study, we set up a method for a rapid and accurate measurement of phagosomal pH in PMNs with the use of Candida albicans doubly labeled with a pH-insensitive and a pH-sensitive probe and flow cytometry. METHODS: Heat-killed, serum-opsonized C. albicans were doubly labeled with fluorescein, a pH-sensitive probe, and rhodamine, a pH-insensitive probe, and incubated with human PMNs. Flow cytometric readings of PMN-associated Candida were then taken, and the intraphagosomal pH was calculated on the basis of the ratio of fluorescein:rhodamine fluorescence by using a calibration curve obtained after equilibration of phagosomal pH with different external pH values after addition of digitonin. RESULTS: A rapid rise in phagosomal pH, which reached pH 7.8, was observed 2 min after initiation of phagocytosis and progressively declined to pH 6.9 after 15 min. Such a rise was not observed in PMNs with defective microbicidal activity (deficient in nicotinamide adenine dinucleotide phosphate oxidase), where phagosomal pH dropped to pH 6.6, 2 min after phagocytosis. The abnormal initial acidification in PMNs deficient in nicotinamide adenine dinucleotide phosphate oxidase was prevented by using lysosomotropic weak bases or the vacuolar-type H(+) pump inhibitor concanamycin A. CONCLUSIONS: Phagosomal pH of PMNs can be easily and accurately measured by dual fluorescence flow cytometry. The method can be applied to assess phagosomal pH in PMNs with defective microbicidal activity and to monitor the outcome of pharmacologic interventions aimed at correcting its abnormalities.     

Characterization of protein kinase C from normal and transformed cultured murine fibroblasts

Protein kinase C of normal and ras-transformed NIH 3T3 cells was purified by chromatography on TSK DEAE-5PW, threonine-Sepharose, and TSK phenyl-5PW columns. Comparison of the fibroblast enzyme with several types of rat brain protein kinase C by chromatography on a hydroxyapatite column and by immunoblotting, indicates that both normal and transformed fibroblasts possess only one of the four subspecies of protein kinase C which have been identified in brain tissues. This subspecies presumably has the structure encoded by alpha-sequence or a closely related sequence. No significant difference was seen between those enzymes purified from normal and transformed fibroblasts.