Analytical methods for the study of liver cell proliferation.

Various cytometric methods for analysis of regenerating rat liver growth (DNA ploidy distributions, binucleation, and DNA synthesis by in vivo BrdUrd incorporation) were evaluated. The overall hepatocellular growth rate (labeling index), the binucleation rate, and separate indices for mononuclear and binuclear cells could be measured simply by microscope counting of collagenase-isolated hepatocytes immunostained for BrdUrd. Flow cytometry of cells stained for BrdUrd and DNA provided labeling indices for the various hepatocellular DNA ploidy classes as well as for nonparenchymal cells (identified by their size-dependent light scatter), but could not distinguish between mononuclear and binuclear hepatocytes. Image cytometry, using fluorescence or Feulgen staining, was inferior to flow cytometry in terms of speed and DNA resolution, but allowed a complete analysis of all hepatocellular DNA ploidy and nuclearity classes. It may therefore be the method of choice, particularly for analysis of liver cell cultures from which single cells are not easily obtained. Fluorescence staining would seem to be preferable to Feulgen staining, since the latter could not be used simultaneously with BrdUrd staining and therefore required a two-step analysis. A non-immunological method, based on the ability of incorporated BrdUrd to quench DNA staining by a Hoechst dye, could only be applied to isolated nuclei, thus giving no information about binucleation. The latter method may be useful for analysis of tumors which are difficult to dissociate to intact whole cells.     

Flow cytometric estimation of cell cycle parameters using a monoclonal antibody to bromodeoxyuridine

An estimation of cell kinetic parameters was made by simultaneous flow cytometric measurements of DNA and bromodeoxyuridine (BrdUrd) contents of cells. The procedure described in this paper involves the incorporation of BrdUrd by S phase cells, labeling the BrdUrd with an indirect immunofluorescent technique using a monoclonal anti-BrdUrd antibody, and staining DNA with propidium iodide (PI). The amount of incorporated BrdUrd in HeLa cells was proportional to that of synthesized DNA through S phase. For all cell lines examined, the pattern of BrdUrd incorporation was essentially the same and the rate of DNA synthesis during S phase was not constant. The bivariate BrdUrd/DNA distributions showed a horse-shoe pattern, maximum in the mid S phase and minimum in the early and late S phases. Furthermore, the durations of cell cycle (Tc) and S phase (Ts) were estimated from a FLSm (fraction of labeled cells in mid S phase) curve that was generated by plotting the percentage of BrdUrd pulse-labeled cells in a narrow window defined in the mid S phase of the DNA histogram. The values of these parameters in NIH 3T3, HeLa S3, and HL-60 cells were in good accordance with the reported data. This FCM method using the monoclonal anti-BrdUrd antibody allows rapid determination of both cell cycle compartments and also Ts and Tc without the use of radioactive DNA precursors.     

Cell cycle analysis of synchronized chinese hamster cells using bromodeoxyuridine labeling and flow cytometry

Summary Chinese hamster ovary cells were synchronized into purified populations of viable G1-, S-, G2-, and M-phase cells by a combination of methods, including growth arrest, aphidicolin block, cell cycle progression, mitotic shake-off, and centrifugal elutriation. The DNA content and bromodeoxyuridine (BrdUrd) labeling index were measured in each purified fraction by dual-parameter flow cytometry. The cell cycle distributions determined from the DNA measurements alone (single parameter) were compared with those calculated from both DNA and BrdUrd data (dual parameter). The results show that highly purified cells can be obtained using these methods, but the assessed purity depends on the method of cell cycle analysis. Using the single versus dual parameter measurement to determine cell cycle distributions gave similar results for most phases of the cell cycle, except for cells near the transition from G1- to S-phase and S- to G2-phase. There the BrdUrd labeling index determined by flow cytometry was more sensitive for detecting small amounts of DNA synthesis. As an alternative to flow cytometry, a simple method of measuring BrdUrd labeling index on cell smears was used and gave the same result as flow cytometry. Measuring both DNA content and DNA synthesis improves characterization of synchronized cell populations, especially at the transitions in and out of S-phase, when cells are undergoing dramatic shifts in biochemical activity.     

Application of Biotin, Digoxigenin or Fluorescein Conjugated Deoxynucleotides to Label DNA Strand Breaks for Analysis of Cell Proliferation and Apoptosis Using Flow Cytometry

A flow cytometric method has recently been developed using biotinylated dUTP (b-dUTP) in a reaction catalyzed by terminal deozynucleotidyl transferase (TdT) to identify the endonuclease-induced DNA strand breaks occurring during apoptosis. Counterstaining of DNA makes it possible to relate apoptosis to cell cycle position or DNA index. In the present study, we compared this method with one using digoxigenin-conjugated dUTP (d-dUTP) to label apoptotic cells. The discrimination of apoptotic from nonapoptotic cells was similar when incorporation of d-dUTP was compared with b-dUTP. Both techniques resulted in a 20-30 fold increase in staining of apoptotic over nonapoptotic cells although somewhat less background fluorescence was observed with the d-dUTP. Direct labeling with fluo-resceinated dUTP (f-dUTP) was less sensitive in detecting DNA strand breaks, but had the advantage of simplicity. The principle of labeling DNA strand breaks using TdT was also employed to identify DNA replicating cells. To this end, the cells were incubated in the presence of BrdUrd, then exposed to UV light to selectively photolyse DNA containing the incorporated BrdUrd. DNA strand breaks resulting from the photolysis were then labeled with b-dUTP or d-dUTP. This approach is an alternative to immunocytochemical detection of BrdUrd incorporation, but unlike the latter does not require prior DNA denaturation, thus can be applied when the denaturation step must be avoided. The method was sensitive enough to recognize DNA synthesizing cells that were incubated with BrdUrd for only 5 min, the equivalent of replication of less than 1% of the cell's genome. The discrimination between apoptotic vs. BrdUrd incorporating-cells is based on different extractability of DNA following cell fixation. This method can be applied to analyze both cell proliferation (DNA replication) and death (by apoptosis) in a single measurement.     

Application of Biotin,Digoxigenin or Fluorescein Conjugated Deoxynucleotides to Label DNA Strand Breaks for Analysis of Cell Proliferation and Apoptosis Using Flow Cytometry

A flow cytometric method has recently been developed using biotinylated dUTP (b-dUTP) in a reaction catalyzed by terminal deozynucleotidyl transferase (TdT) to identify the endonuclease-induced DNA strand breaks occurring during apoptosis. Counterstaining of DNA makes it possible to relate apoptosis to cell cycle position or DNA index. In the present study, we compared this method with one using digoxigenin-conjugated dUTP (d-dUTP) to label apoptotic cells. The discrimination of apoptotic from nonapoptotic cells was similar when incorporation of d-dUTP was compared with b-dUTP. Both techniques resulted in a 20–30 fold increase in staining of apoptotic over nonapoptotic cells although somewhat less background fluorescence was observed with the d-dUTP. Direct labeling with fluo-resceinated dUTP (f-dUTP) was less sensitive in detecting DNA strand breaks, but had the advantage of simplicity. The principle of labeling DNA strand breaks using TdT was also employed to identify DNA replicating cells. To this end, the cells were incubated in the presence of BrdUrd, then exposed to UV light to selectively photolyse DNA containing the incorporated BrdUrd. DNA strand breaks resulting from the photolysis were then labeled with b-dUTP or d-dUTP. This approach is an alternative to immunocytochemical detection of BrdUrd incorporation, but unlike the latter does not require prior DNA denaturation, thus can be applied when the denaturation step must be avoided. The method was sensitive enough to recognize DNA synthesizing cells that were incubated with BrdUrd for only 5 min, the equivalent of replication of less than 1% of the cell's genome. The discrimination between apoptotic vs. BrdUrd incorporating-cells is based on different extractability of DNA following cell fixation. This method can be applied to analyze both cell proliferation (DNA replication) and death (by apoptosis) in a single measurement.     

Characterization and cell cycle kinetics of hepatocytes during rat liver regeneration: in vivo BrdUrd incorporation analysed by flow cytometry and electron microscopy

The incorporation of bromodeoxyuridine (BrdUrd) into newly synthesized DNA has been analysed during hepatocellular regeneration induced by partial hepatectomy in young rats. The kinetic state of the liver has been studied by flow cytometric analysis of the incorporated BrdUrd, while the fine localization of DNA replication sites through the cell cycle has been investigated at the ultrastructural level by the immunogold technique. Eighteen hours after partial hepatectomy flow cytometry revealed an early S phase distribution which corresponded to a specific staining of the interchromatin domains of the hepatocyte nucleus. Thirty-four hours after hepatectomy, on the other hand, when most cells were in late S, a specific staining of heterochromatin domains was observed. The effect of the BrdUrd technique on nuclear aggregation has also been analysed and discussed. The results demonstrate that specific patterns of DNA replication can be recognized during the cell cycle and that flow cytometry and electron microscopy appear to be complementary in the kinetic study of liver regeneration.     

Bromodeoxyuridine labeling and flow cytometric identification of replicating Saccharomyces cerevisiae cells: lengths of cell cycle phases and population variability at specific cell cycle positions.

An immunofluorescent staining procedure has been developed to identify, with flow cytometry, replicating cells of Saccharomyces cerevisiae after incorporation of bromodeoxyuridine (BrdUrd) into the DNA. Incorporation of BrdUrd is made possible by using yeast strains with a cloned thymidine kinase gene from the herpes simplex virus. An exposure time of 4 min to BrdUrd results in detectable labeling of the DNA. The BrdUrd/DNA double staining procedure has been optimized and the flow cytometry measurements yield histograms comparable to data typically obtained for mammalian cells. On the basis of the accurate assessment of cell fractions in individual cell cycle phases of the asynchronously growing cell population, the average duration of the cell cycle phases has been evaluated. For a population doubling time of 100 min it was found that cells spend in average 41 min in the replicating phase and 24 min in the G2+M cell cycle period. Assuming that mother cells immediately reenter the S phase after cell division, daughter cells spend 65 min in the G1 cell cycle phase. Together with the single cell fluorescence parameters, the forward-angle light scattering intensity (FALS) has been determined as an indicator of cell size. Comparing different temporal positions within the cell cycle, the determined FALS distributions show the lowest variability at the beginning of the S phase. The developed procedure in combination with multiparameter flow cytometry should be useful for studying the kinetics and regulation of the budding yeast cell cycle.     

A rapid and simple estimation of cell cycle parameters by continuous labeling with bromodeoxyuridine

The DNA synthesis time (Ts) and other related cell cycle parameters were roughly estimated in HeLa cells labeled with bromodeoxyuridine (BrdUrd) for various durations by using the flow cytometrical technique. The labeling indices increased in proportion to time after addition of BrdUrd. The Ts can be calculated from the slope of the regression line obtained by plotting the serial labeling indices against the labeling time and was equivalent to the value determined by fraction labeled cells in mid S-phase (FLSm) method. These parameters would be determined by only two samples labeled for different times. This simple method using BrdUrd provides rough but rapid estimation of Ts and other cell cycle parameters without complicated mathematical procedures, in addition to cell cycle partition of cell populations.     

SCE induction and harlequin staining in mycoplasma-contaminated Chinese hamster cells

Chinese hamster V79 and CHO cells infected with Mycoplasma hyorhinis show elevated sister-chromatid exchange (SCE) levels but normal cell proliferation and levels of chromosomal aberrations when compared with uninfected cells. Harlequin staining patterns differ from those seen with uninfected cells at similar levels of bromodeoxyuridine (BrdUrd), indicating that BrdUrd is rapidly depleted from the medium by the mycoplasmal uridine phosphorylase and therefore becomes unavailable over the two cell cycles necessary for harlequin staining. Continuous treatment with the antibiotic minocycline restores the SCE level and harlequin staining to that seen in uncontaminated cells. The results suggest that mycoplasma infection should be suspected if harlequin staining patterns indicate a sudden decrease in incorporation of BrdUrd in cells grown in normal levels of BrdUrd.     

Flow cytometric detection of mitotic cells using the bromodeoxyuridine/DNA technique in combination with 90 degrees and forward scatter measurements

Mitotic cells could be well discriminated from the cells in the G1-, S- and G2-phases of the cell cycle using pulse labeling of S-phase cells with bromodeoxy-uridine (BrdUrd) and staining of the cells for incorporated BrdUrd and total DNA content. Unlabeled G2- and M-phase cells could be measured as two separate peaks according to propidium iodide fluorescence. M-phase cells showed lower propidium iodide fluorescence emission compared to G2-phase cells. The fluorescence difference of M- and G2-phase cells was caused by the different thermal denaturation of their DNA. Best separation of M- and G2-phase cells was obtained after 30-50 min heat treatment at 95 degrees C. Mitotic index could be measured if no unlabeled S-phase cells were present in the cell culture. With additional measurements of 90 degree scatter and/or forward scatter signals, mitotic cells could be clearly discriminated from both unlabeled G2- and S-phase cells. The correct discrimination (about 99%) of mitotic cells from interphase cells was verified by visual analysis of the nuclear morphology after selective sorting. Unlabeled and labeled mitotic cells could be observed as pulse-labeled cells progressed through the cell cycle. We conclude that this modified BrdUrd/DNA technique using prolonged thermal denaturation and the simultaneous measurement of scatter signals may offer additional information especially in the presence of BrdUrd-unlabeled S-phase cells.     

Statistical patterns of the anomalous staining of 5-bromodeoxyuridine-substituted chromosomes

Five large chromosome segments showing sometimes an abnormal staining were found in the genome of Chinese hamster (clone 237). Three types of abnormal staining were recorded. After one round of replication in the presence of BrdUrd these segments showed a hetero-staining, whereas after two rounds of replication the same segments showed iso-dark or iso-light staining. Pulse labeling with 3H-thymidine showed that all these segments were the late-replicating ones. The labeling proceeded according to all-or-none principle; in a given cell all five segments showed either presence or absence of the label. On the contrary, the abnormal staining was statistically distributed among these segments. These results are in disagreement with the current view that the abnormal staining is associated with asymmetrical distribution of thymine among two strands of DNA duplex. The above regularities are considered as an argument for the two-stranded model of chromosome.     

Mapping of the pattern of DNA replication in polytene chromosome from Chironomus thummi using monoclonal anti-bromodeoxyuridine antibodies

We present results from a nonautoradiographic study of DNA replication in polytene chromosomes from dipteran larvae. Monoclonal antibodies with specificity for 5-bromodeoxyuridine (BrdUrd) were used to localize by indirect immunofluorescence the sites of BrdUrd incorporation and to follow the dynamics of DNA synthesis in salivary gland cells of 4th instar Chironomus thummi larvae. This technique presents numerous advantages over autoradiographic procedures and allows mapping of DNA synthesis patterns at the level of resolution of one chromosomal band. Several replication patterns were observed, classified according to characteristic features, and tentatively assigned to specific periods of the S-phase. In early S-phase, DNA synthesis is first detectable in puffs and interbands, later in bands. Most chromosomal bands appear to initiate DNA synthesis synchronously; however, in bands within centromeric and heterochromatic regions the start of synthesis is delayed. At mid S-phase, all the bands show uniform staining. Subsequent staining patterns are increasingly differential with the bands displaying characteristic fluorescence intensities. As replication progresses through the late S-phase period, the chromosomes show a decreasing number of fluorescent bands. The last bands to terminate replication are located in centromeric and heterochromatic DNA-rich regions and a few bands of low DNA content in region IIAa-c.     

Cytochemistry for bromodeoxyuridine/DNA analysis: stoichiometry and sensitivity

This report describes an improved immunochemical procedure for staining cells in suspension for amount of incorporated bromodeoxyuridine (BrdUrd) and total DNA. In this procedure, cellular DNA is partially denatured by extracting the cells with 0.1 M HCl and then heating them to 80 degrees C in a 50% formamide solution. The cells are then immunofluorescently stained using a monoclonal antibody against BrdUrd in single-strand DNA (ssDNA) and counterstained for DNA content with propidium iodide (PI), a dye that fluoresces preferentially when bound to double-strand DNA (dsDNA). We show that the relative amounts of immunofluorescently stained BrdUrd in ssDNA and PI in dsDNA can be altered reciprocally by changing the formamide concentration, denaturation time, and denaturation temperature. We show that this new immunochemical staining procedure allows more complete DNA denaturation so that fivefold lower levels of BrdUrd incorporation can be quantified. In addition, we show that the BrdUrd-linked immunofluorescence achieved using the new denaturation procedure is more linearly related to cellular BrdUrd content than that achieved after acid DNA denaturation. However, cell loss is sufficiently severe with the thermal denaturation procedure that it may not be applicable to all cell types.     

Retinoblastoma cell cycling

Techniques for the measurement of bromodeoxyuridine (BrdUrd) positive cells generally include either microscopic evaluation of paraffin embedded sections or measurements on cell suspensions using a fluorescent activated cell sorter. The accuracy of these measurements and their correlations can be affected by a number of technical and intrinsic tumor factors. Extrinsic parameters including degree of necrosis and tumor growth fraction are less easily analyzed in BrdUrd stained material. Retinoblastoma tumor cell cycling was prospectively studied in 11 children using in vivo and one child using in vitro BrdUrd. BrdUrd measurements were made by staining cell suspensions or sections of paraffin embedded tumor and analyzing by microscopy. Approximately 14% of viable cells were in the synthesis-phase of the cell cycle. The correlation between BrdUrd in cell suspensions and BrdUrd in paraffin embedded sections did not reach significance (r = 0.48). DNA analysis of these tumors was also performed using flow cytometry. Nine tumors were found to have a normal diploid DNA content, one had a G1 peak below the diploid control, two had a G1 peak above the diploid control, and one had two G1 peaks (a diploid and a hyperdiploid peak). There was no correlation between abnormal DNA content and the percent of cells in synthesis.     

The use of bromodeoxyuridine labeling in the human lymphocyte HGPRT somatic mutation assay

The autoradiographic assay developed by Strauss and Albertini (1979) to quantitate human in vivo somatic mutation at the hypoxanthine guanine phosphoribosyl-transferase locus uses tritiated thymidine to identify mutant cells by their ability to pass through 'S' phase in the presence of 6-thioguanine. An alternative method, based on the incorporation of bromodeoxyuridine (BrdUrd) into the DNA of proliferative cells, followed by differential staining with the fluorescence-plus-Giemsa method, was used to identify 3 classes of lymphocyte nuclei: (a) small darkly stained nuclei, (b) large, reddish-colored nuclei with an apparent nucleolus, and (c) large, bluish-colored nuclei. By double labeling with BrdUrd and tritiated thymidine, it was determined that only the nuclei of the third class had incorporated BrdUrd. These results demonstrate that the technique used for sister-chromatid differentiation can be used to detect putative HGPRT mutants and to determine variant frequencies at the HGPRT locus.     

A simple method for identification of S phase nuclei in Vicia faba root meristems using BrdUrd labeling and indirect immunofluorescence (comparison with 3H-thymidine incorporation)

A modified immunocytochemical method for identification of S-phase cells in root meristems is desribed. The technique combines incorporation of BrdUrd, rapid isolation of cell nuclei and indirect immunocytochemical detection of BrdUrd-labeled areas of chromatin using monoclonal anti-BrdUrd (I) and FITC-conjugated (II) antibodies. The labeling indexes calculated using ³H-thymidine autoradiography and BrdUrd-immunofluorescence in root meristems of Vicia faba subsp. minor were found comparable. However, the increased sensitivity of fluorescent staining reveals an enhanced complexity of visible structure emerging during successive periods of S-phase, allowing for discriminating not only quantitative but also qualitative aspects of nuclear labeling patterns characteristic for specific periods of DNA replication.     

Flow cytometric analysis of DNA replication during the differentiation of 3T3-L1 preadipocytes

We have employed a flow cytometric method of monitoring DNA synthesis in order to study the stimulation of DNA replication during the induction of adipocyte differentiation in the preadipocyte cell line 3T3-L1. When confluent monolayers of this cell line are treated with a mixture of methyl isobutyl xanthine, dexamethasone, and insulin (MDI), they undergo at least one round of cell division, which is followed by the de novo synthesis of many enzymes that are involved in the formation of lipid. If the MDI-treated cells are incubated in iododeoxyuridine (IdUrd)- or bromodeoxyuridine (BrdUrd)-containing medium and subsequently stained with antibodies specific for these base analogues and with propidium iodide (PI), the kinetics of the induction of replication can be monitored. No differences in the patterns of IdUrd incorporation versus PI staining were observed between exponentially growing 3T3-L1 cells and those that had been stimulated to replicate DNA with MDI. In addition, we developed a flow cytometric (FCM) method for staining fatty acid synthetase and localizing the antigen in the G1 phase. We have thus demonstrated the feasibility of this methodology for correlating by FCM the production of enzymes such as fatty acid synthetase with IdUrd and BrUrd incorporation. The technique should permit studies of the inhibition of differentiation of adipocytes by halogenated pyrimidines.     

Simultaneous flow cytometric detection of cellular c-myc protein, incorporated bromodeoxyuridine, and DNA

We describe a multivariate flow cytometric technique for simultaneous analysis of specific nuclear protein, bromodeoxyuridine (BrdUrd) incorporated into DNA and DNA content in single cells in suspension. The procedure involves fixation of BrdUrd-exposed cells with paraformaldehyde, heat denaturation of cellular DNA, followed by sequential immunochemical reactions to label incorporated BrdUrd and nuclear protein, and finally staining of total DNA with propidium iodide. The cells are analyzed flow cytometrically and multivariate data acquired in list mode to facilitate analyses of heterogeneous subpopulations. We applied this technique to measure c-myc protein, incorporated BrdUrd, and DNA content in subpopulations present in a recombinant Chinese hamster ovary (CHO) cell line carrying approximately 800 copies of murine c-myc sequences under control of an inducible heat shock promoter.     

Immediate bromodeoxyuridine labelling of unseparated human bone marrow cells ex vivo is superior to labelling after routine laboratory processing

It is important to evaluate the proliferation of bone marrow cells in several disease conditions and during treatment of patients with for example cytokines. Labelling with bromodeoxyuridine (BrdUrd), immunocytochemical staining with anti-BrdUrd antibody and analysis by flow cytometry provides a reliable and reproducible technique for estimation of the fraction of cells that incorporated BrdUrd into DNA during S-phase. We have compared immediate BrdUrd labelling of unseparated bone marrow cells with the previously used labelling in the laboratory after routine separation of the mononuclear cells. Bone marrow aspirates from seven lymphoma patients without bone marrow involvement were studied with these two methods. We found higher BrdUrd labelling indices (LI) in the mononuclear cells, when cells were labelled immediately. A large variation in LI was found between patients. Our results suggest that ex vivo BrdUrd labelling of bone marrow cells should be performed immediately after aspiration and before separation, because these data are closer to values reported from in vivo labelling with BrdUrd.     

Detection of bromodeoxyuridine incorporation in mammalian chromosomes by a bromodeoxyuridine antibody

A commercially available bromodeoxyuridine (BrdUrd) antibody was used to demonstrate sister chromatid differentiation (SCD) and to evaluate sister chromatid exchanges (SCEs) in V79 Chinese hamster cells. V79 cells were cultivated for one cell cycle in the presence of BrdUrd, followed by a second cell cycle in the absence of BrdUrd. Chromosome preparations were stained by a common immunologic staining technique. The staining pattern observed is similar to that after FPG (fluorescent plus Giemsa) staining, though with reverse staining specificity. The sensitivity of BrdUrd detection is enhanced by a factor of 20 compared to the FPG technique and thus allows the evaluation of SCEs at very low BrdUrd concentrations. The application of the antibody technique gives information about the origin and localization of SCEs and produces further evidence for the spontaneous occurrence of SCEs.