Bromodeoxyuridine (BrdU) immunocytochemistry by exonuclease III (Exo III) digestion.

A new procedure is described to generate single-stranded DNA by exonuclease III (Exo III) digestion for bromodeoxyuridine (BrdU) immunocytochemistry on tissue sections. We compared this procedure with the most widely used procedure of DNA denaturation with 2 N HCl. In vivo and in vitro pulse and continuous labelling of tissues and cells were used. The specimens were fixed in formalin, ethanol, glutaraldehyde, Carnoy's, Bouin's or Zamboni's fixative and embedded in paraffin or used unfixed as cryostat sections or cytospin preparations. After Exo III digestion, BrdU substituted DNA was detected irrespective of the fixation procedure applied. The optimal protocol for nuclease digestion appeared to be simultaneous incubation, of 10 Units Exo III per ml EcoRI buffer and anti-BrdU monoclonal antibody at 37 degrees C. The advantages of Exo III digestion for BrdU immunocytochemistry compared to acid denaturation were: less non-specific nuclear background reactivity, no DNA renaturation, less DNA loss, optimal nuclear morphology, increase in antibody efficiency and the possibility for simultaneous detection of acid-sensitive tissue constituents. Disadvantages of the Exo III digestion are decreased sensitivity and the need for more rigorous pepsin pretreatment. We conclude that Exo III digestion of DNA is an appropriate alternative for acid denaturation for BrdU immunocytochemistry on sections of pulse-labelled specimens.     

Bromodeoxyuridine (BrdU) immunocytochemistry by exonuclease III (Exo III) digestion

Summary A new procedure is described to generate single-stranded DNA by exonuclease III (Exo III) digestion for bromodeoxyuridine (BrdU) immunocytochemistry on tissue sections. We compared this procedure with the most widely used procedure of DNA denaturation with 2 N HCl. In vivo and in vitro pulse and continuous labelling of tissues and cells were used. The specimens were fixed in formalin, ethanol, glutaraldehyde, Carnoy's, Bouin's or Zamboni's fixative and embedded in paraffin or used unfixed as cryostat sections or cytospin preparations. After Exo III digestion, BrdU substituted DNA was detected irrespective of the fixation procedure applied. The optimal protocol for nuclease digestion appeared to be simultaneous incubation, of 10 Units Exo III per ml EcoRI buffer and anti-BrdU monoclonal antibody at 37° C. The advantages of Exo III digestion for BrdU immunocytochemistry compared to acid denaturation were: less non-specific nuclear background reactivity, no DNA renaturation, less DNA loss, optimal nuclear morphology, increase in antibody efficiency and the possibility for simultaneous detection of acid-sensitive tissue constituents. Disadvantages of the Exo III digestion are decreased sensitivity and the need for more rigorous pepsin pretreatment. We conclude that Exo III digestion of DNA is an appropriate alternative for acid denaturation for BrdU immunocytochemistry on sections of pulse-labelled specimens.     

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.     

Flow cytometric analysis of experimental parameters for the immunofluorescent labeling of BrdUrd in various tumour cell lines

Summary This report describes the results of the comparison of three different methods and three monoclonal antibodies to stain cells in suspension for incorporated bromodeoxyuridine and total DNA content. The procedures were tested in three different experimental tumour cell lines. The sensitivity of the different procedures was expressed as the ratio of the anti-BrdUrd fluorescence intensities of the S and G1 phase cells (FS/FG1 ratio). There were remarkable differences in sensitivity between the different procedures. With the heat denaturation the most favourable FS/FG1 ratio's were obtained but substantial cell loss occurred during this procedure which is a disadvantage for clinical application. With the pepsin digestion + acid denaturation procedure cell loss was negligible. The standard acid denaturation procedure was inferior to the other two methods. Using the pepsin digestion + acid denaturation procedure we examined the variations in sensitivity for the different monoclonal antibodies and cell lines and the influence of BrdUrd concentration, labelingtime and cell concentration. The binding characteristics for the various antibodies differed considerably in our hands. Only with the IU4 antibody we obtained FS/FG1 ratio's comparable with those desenbed in the literature. No difference was observed between the cell lines. Variation in cell concentration between 1 × 10⁴ to 1 × 10⁶ ml nor BrdUrd concentration appeared to influence the sensitivity of the procedure. A labelingtime of 1 h or even 30 min seems to be more than sufficient for an optimal FS/FG1 ratio.Our results indicate that using the appropriate antibody and immunofluorescence BrdUrd can be detected by flow cytometry, after incorporation into the DNA of tumour cells under a wide range of culture conditions.For clinical application, the pepsin digestion + acid dena uration method in combination with IU4 antibody seems to be the procedure of choice due to its good reproducibility, sensitivity and its low cell loss.     

Flow cytometric analysis of experimental parameters for the immunofluorescent labeling of BrdUrd in various tumour cell lines

This report describes the results of the comparison of three different methods and three monoclonal antibodies to stain cells in suspension for incorporated bromodeoxyuridine and total DNA content. The procedures were tested in three different experimental tumour cell lines. The sensitivity of the different procedures was expressed as the ratio of the anti-BrdUrd fluorescence intensities of the S and G1 phase cells (FS/FG1 ratio). There were remarkable differences in sensitivity between the different procedures. With the heat denaturation the most favourable FS/FG1 ratio's were obtained but substantial cell loss occurred during this procedure which is a disadvantage for clinical application. With the pepsin digestion + acid denaturation procedure cell loss was negligible. The standard acid denaturation procedure was inferior to the other two methods. Using the pepsin digestion + acid denaturation procedure we examined the variations in sensitivity for the different monoclonal antibodies and cell lines and the influence of BrdUrd concentration, labelingtime and cell concentration. The binding characteristics for the various antibodies differed considerably in our hands. Only with the IU4 antibody we obtained FS/FG1 ratio's comparable with those described in the literature. No difference was observed between the cell lines. Variation in cell concentration between 1 x 10(4) to 1 x 10(6) ml nor BrdUrd concentration appeared to influence the sensitivity of the procedure. A labelingtime of 1 h or even 30 min seems to be more than sufficient for an optimal FS/FG1 ratio. Our results indicate that using the appropriate antibody and immunofluorescence BrdUrd can be detected by flow cytometry, after incorporation into the DNA of tumour cells under a wide range of culture conditions.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Human Papillomavirus Detection In Cervical Cells By In Situ Hybridization With Biotinylated Probes

We have investigated the applicability of human papillomavirus (HPV) DNA detection by in situ hybridization with biotinylated probes in epithelial cells obtained from the cervix using a cotton tip swab. We describe a simple procedure for obtaining homogeneous cell samples and good preservation of cellular structure. This is achieved by pretreatment of cells with L-cysteine before hybridization. Separate denaturation of cellular DNA and probe DNA is also necessary for satisfactory results. Both benign HPV DNA 6/11 and potentially oncogenic HPV DNA 16/18 could be identified in our series. In situ hybridization on cervical scrapes is a rapid, simple and very specific method for detecting patients infected with oncogenic HPV types.     

In situ hybridization and chromosome banding in mammalian species

Chromosome banding is often required in conjunction with fluorescent in situ hybridization of labelled probes for chromosome painting, satellite DNA and low-copy sequences to allow identification of chromosomes and simultaneous probe localization. Here, we present a method that reveals both patterns with only one observation step. The band pattern is produced by restriction-enzyme digestion of chromosomes, followed by fixation with paraformaldehyde in PBS, a short chromosome denaturation step in hybridization solution, and then standard in situ hybridization, washing and detection protocols. Using a range of different mammalian species, chromosome-banding patterns were immediately recognizable, although synchronisation procedures normally required for high- resolution G-banding were not needed. Unlike other methods available, only one round of observation is required using a conventional fluorescence microscope, the method works without modification in many species, and in situ hybridization is not used for chromosome identification (allowing multiple targets and minimizing background). The banding pattern is probably generated by a combination of DNA dissolution and heterochromatin reorganisation after enzyme digestion, followed by paraformaldehyde fixation of the new chromatin structure and incomplete denaturation. The method is of widespread utility in comparative genomics and genome organization programmes.     

An improved immunocytochemical procedure for high-sensitivity detection of incorporated bromodeoxyuridine

This report describes an improved immunochemical procedure to stain cells in suspension for incorporated bromodeoxyuridine (BrdUrd) and total DNA content. The procedure consists of five steps: chromatin proteins are extracted by treating with 0.1 M HCl and 0.7% Triton X-100 to facilitate DNA denaturation and to minimize nonspecific staining; cellular DNA is denatured by heating to 100 degrees C in distilled water; BrdUrd in single-stranded DNA (ssDNA) is stained using an immunochemical procedure; autofluorescence is reduced using sodium borohydride (NaBH4); and DNA is stained with the fluorescent dye propidium iodide. With this procedure, the BrdUrd incorporated by CHO cells during periods as short as a few seconds can be detected using flow cytometry. In addition, the stoichiometry of the immunofluorescent staining procedure is high.     

Isolation of in vitro synthesized covalently closed circular double-stranded DNA by selective denaturation and filtration

Based upon their resistance to irreversible denaturation, covalently closed circular (CCC) DNA (non-nicked, double-stranded circular molecules) can be purified by alkaline denaturation, neutralization, and filtration through a nitrocellulose membrane. This procedure offers a simple means of isolating in vitro synthesized CCC DNA molecules. The preparations of molecules obtained by this method consisted of 91-97% CCC DNA and contained no detectable inhibitors of biological activity or enzymatic digestion.     

Effects of denaturation with HCl on the immunological staining of bromodeoxyuridine incorporated into DNA

Immunochemical procedures for detection of BrdUrd incorporated into DNA require a denaturation step of DNA. Denaturation with HCl is widely used for flow cytometric analysis of the cell cycle and for histological preparations. This brief communication describes an attempt to standardize a denaturation procedure with HCl. Various denaturation conditions at 20 degrees C were examined for human promyelocytic leukemia cells (HL-60 cells) fixed in ethanol. After denaturation of DNA, the cells were stained by an indirect immunofluorescence method using a commercially available monoclonal anti-BrdUrd antibody or by propidium iodide. The relative fluorescence intensities of stained BrdUrd and double-stranded DNA were altered reciprocally by changing HCl concentration and/or denaturation time. Treatment with 4N HCl for 10-20 min at 20 degrees C allowed denaturation of more than 80% of DNA and the maximum BrdUrd-linked immunofluorescence. Under this condition, the coefficient of variation of the DNA histograms remained relatively small.     

Isolation of in Vitro Synthesized Covalently Closed Circular Double-Stranded DNA by Selective Denaturation and Filtration

Based upon their resistance to irreversible denaturation, covalently closed circular (CCC) DNA (non-nicked, double-stranded circular molecules) can be purified by alkaline denaturation, neutralization, and filtration through a nitrocellulose membrane. This procedure offers a simple means of isolating in vitro synthesized CCC DNA molecules. The preparations of molecules obtained by this method consisted of 91-97% CCC DNA and contained no detectable inhibitors of biological activity or enzymatic digestion.     

Ultraviolet-induced detection of halogenated pyrimidines: simultaneous analysis of DNA replication and cellular markers

BACKGROUND: We describe a new nonenzymatic methodology that allows the simultaneous detection of DNA replication and other cellular markers such as immunophenotyping. DNA replicating cells are identified by their incorporation of halogenated thymidine analogs, e.g., 5-bromo-deoxyuridine (BrdUrd). METHODS: Irradiation with ultraviolet (UV)-B or UV-A light in the presence of Hoechst 33258 and subsequent treatment with a hypotonic buffer makes BrdUrd accessible to monoclonal antibodies (mAb), thus allowing its sensitive detection. RESULTS: The photolysis of BrdUrd in DNA with UV light is sequence dependent and results in DNA damage, allowing the detection of remaining BrdUrd using hypotonic conditions. However, treatment with other inducers of single or double- strand breaks of DNA such as gamma irradiation or hydrogen peroxide did not allow BrdUrd detection. The new methodology is compatible with both mild crosslinking fixation, i.e., aldehydes, or coagulative fixation, i.e., alcohols. The successful identification of CD34+, CD138+, or CD19+ cells out of heterogeneous cell suspensions and their cell-cycle analysis are described. Results correlated very well with acid denaturation (r = 0.972). The average coefficient of variation (CV) of G(1) in the DNA histogram was smaller than 5%, resulting in good preservation of DNA distribution. Also, the signal-to-noise ratio was almost twice as high as for 2N acid denaturation, facilitating convenient discrimination of BrdUrd-positive cells. CONCLUSIONS: In contrast to previous approaches, this methodology eliminates the need for any additional enzymatic treatment such as DNA digestion or strand-break labeling after UV irradiation. The method is fast, convenient, and inexpensive and should be able to promote the use of halogenated pyrimidines in basic and clinical research of cancer, immunology, and pharmacology.     

Isolation of DNA fragments containing replicating growing forks from both E. coli and B. subtilis

Summary By the use of a restriction enzyme digestion of gently lysed E. coli or B. subtilis cells, it is possible to isolate a minute fraction of the total DNA that has an unusually high sedimentation coefficient. Upon inspection of this DNA in the electron microscope, branched DNA fragments are observed. Single branched DNA fragments were analyzed by restriction enzyme and partial denaturation mapping techniques. The fragments appear to have the properties of growing forks excised from in vivo replicating intermediates. In B. subtilis, the minute fraction of DNA was also investigated by transformation assays and found to be greatly enriched for a marker near the origin and slightly enriched for a terminus marker.     

Analysis of integrated avian RNA tumor virus DNA in transformed chicken, duck and quail fibroblasts.

The state of integration of avian sarcoma virus DNA in the genomes of transformed chicken, duck, and quail fibroblasts was deduced by means of restriction enzyme digestion of total cell DNA, gel electrophoresis, and subsequent analysis by the procedure of Southern. The cells used in these studies were either mass-infected cultures or clones of infected cells selected by their ability to form colonies in agar. For both mass-infected cultures and clones of cells of all three species, we found that integration occurred at a specific site on the viral genome but appeared to occur at many sites on the cell genome. At least some of the integrated viral DNA existed as intact nonpermuted species flanked by direct terminal repeats of at least 0.134 megadalton (217 base pairs). For each of 12 transformed quail clones studied, it was possible to detect, after digestion with Kpn I, unique junctions between viral and cellular DNA. That is, at our level of analysis, the integration site on the cell genome for each clone was different. However, within each of the 17 chicken and 9 duck clones of transformed cells, a heterogeneity presumably occurred during the outgrowth of the cell clone population, in that we could not readily detect identifiable cell-virus junction fragments.     

Improved methodology for detecting bromodeoxyuridine in cultured cells and tissue sections by immunocytochemistry

Detection of DNA synthesizing cells may often be achieved by immunocytochemical detection of bromodeoxyuridine (BrdU), which is rapid and appears to give similar results to those found using tritiated thymidine. However, the methodology for detection of BrdU involves a denaturation or digestion step to allow access of the antibody to BrdU incorporated into single- rather than double-stranded DNA. We wished to determine if microwave treatment could be used to enhance the detection of BrdU without the need for any other digestion/denaturation steps. An important consideration was to investigate whether such treatment produces a similar quantitative result, since BrdU detection is usually assessed on the basis of cell number rather than topographical distribution. We have found that microwave treatment can allow considerably lower antibody concentrations and eliminates the need for any other denaturation step. It also reduces the non-specific background staining found when using monoclonal antibodies on mouse tissue. We have performed cell counts and found that the number of BrdU positive cells remains constant for a range of different immunocytochemical parameters. We also report conditions where immunopositivity is adversely affected by changes in technique and describe the optimised conditions for obtaining reproducible results.     

Direct measurement of single-stranded DNA intermediates in mammalian cells by quantitative polymerase chain reaction

Single-stranded DNA (ssDNA) intermediates are formed in multiple cellular processes, including DNA replication and recombination. Here, we describe a quantitative polymerase chain reaction (qPCR)-based assay to quantitate ssDNA intermediates, specifically the 3′ ssDNA product of resection at specific DNA double-strand breaks induced by the AsiSI restriction enzyme in human cells. We protect the large mammalian genome from shearing by embedding the cells in low-gelling-point agar during genomic DNA extraction and measure the levels of ssDNA intermediates by qPCR following restriction enzyme digestion. This assay is more quantitative and precise compared with existing immunofluorescence-based methods.     

Induction of placental alkaline phosphatase in choriocarcinoma cells by 5-bromo-2′-deoxyuridine

Summary Growth of choriocarcinoma cells in the presence of 5-bromo-2′-deoxyuridine (BrdUrd) results in a 30- to 40-fold increase in alkaline phosphatase activity. The effect of BrdUrd is specific for phosphatase with an alkaline pH optimum. The induction by BrdUrd is probably not due to the production of an altered enzyme, since the induced enzyme resembles the basal enzyme in thermal denaturation and kinetic properties. Enzyme induction can be prevented by thymidine but not by deoxycytidine or deoxyuridine. The induction of alkaline phosphatase appears to require incorporation of the BrdUrd into cellular DNA. The presence of BrdUrd in the growth medium is not necessary for alkaline phosphatase induction in proliferating cells containing: BrdUrd-substituted genomes. However, enzyme induction and maintenance of the induced levels of alkaline phosphatase in nonproliferating cells containing BrdUrd-substituted DNA requires the presence of the analogues in the medium. The induction of alkaline phosphatase by BrdUrd in probably an indirect process.     

Induction of placental alkaline phosphatase in choriocarcinoma cells by 5-bromo-2'-deoxyuridine.

Growth of choriocarcinoma cells in the presence of 5-bromo-2'-deoxyuridine (BrdUrd) results in a 30- to 40-fold increase in alkaline phosphatase activity. The effects of BrdUrd is specific for phosphatase with an alkaline pH optimum. The induction by BrdUrd is probably not due to the production of an altered enzyme, since the induced enzyme resembles the basal enzyme in thermal denaturation and kinetic properties. Enzyme induction can be prevented by thymidine but not by deoxycytidine or deoxyuridine. The induction of alkaline phosphatase appears to require incorporation of the BrdUrd into cellular DNA. The presence of BrdUrd in the growth medium is not necessary for alkaline phosphatase induction in proliferating cells containing BrdUrd-substituted genomes. However, enzyme induction and maintenance of the induced levels of alkaline phosphatase in nonproliferating cells containing BrdUrd-substituted DNA requires the presence of the analogues in the medium. The induction of alkaline phosphatase by BrdUrd in probably an indirect process.