Attenuation of apoptotic DNA fragmentation by amiloride.

Amiloride is a K+-sparing diuretic that effectively inhibits the Na+/H+ transporter in the plasma membrane of most mammalian cells. We have examined the effects of amiloride on the progression of apoptosis in HL-60 cells induced by camptothecin (CAM), cycloheximide (CHX), and 20 Gy gamma irradiation. Spectrofluorometric measurements on cell populations showed an inhibition of Na+/H+ transporter activity and a corresponding decrease in intracellular pH following treatment with amiloride alone, or in combination with the apoptosis-inducing agents. Flow cytometric cell cycle analysis, in combination with DNA strand break analysis, indicated that amiloride diminished endonuclease-mediated degradation of nuclear chromatin 3 h following treatment with CAM or CHX, and prevented degradation for 3 h following gamma radiation treatment. Apoptosis-associated DNA degradation was significantly greater for all three agents in the absence of amiloride. Protection from radiation-induced apoptosis was transient, since apoptotic subpopulations were observed, but still at a decreased level, 5 h following irradiation. Amiloride was as effective as zinc, an inhibitor of Ca2+/Mg2+-dependent endonucleases, in reducing or delaying the onset of endonuclease activity. Data presented show that effects of amiloride on membrane Na+/H+ transporter activity and intracellular pH can potentially affect apoptotic signaling cascades, leading to a retardation in the rate of progression to an apoptotic cell death. Results also point to the involvement of intracellular pH and Ca2+ in the regulation of apoptotic endonuclease activity, and the need for a functional Na+/H+ exchanger for the induction of apoptosis.

Apoptosis induced with different cycle-perturbing agents produces differential changes in the fluorescence lifetime of DNA-bound ethidium bromide.

Fluorescence lifetime analysis was used in combination with conventional flow cytometric analysis to monitor changes in residual chromatin in apoptotic HL-60 cell populations following treatment with camptothecin, cycloheximide, genistein, H7, and gamma radiation. Data presented show that all of these metabolic inhibitors, which act through different signaling cascades, produce apoptotic subpopulations with decreased but different lifetimes for DNA-bound ethidium bromide (EB). Additionally, treatment with certain agents reduced the fluorescence lifetime in the apoptotic cells prior to extensive endonuclease degradation of DNA and the appearance of the typical sub-G0/G1 peak in the DNA histogram. A lifetime value of 21.15 +/- 0.12 ns was obtained for EB bound to nonapoptotic cells, while values for EB bound to the apoptotic subpopulations following treatment with the different agents were: camptothecin, 19.87 +/- 0.08 ns; cycloheximide, 19.39 +- 0.02 ns; H7, 19.77 +/- 0.03 ns; genistein, 20.04 +/- 0.04 ns; and gamma radiation, 19.67 +/- 0.03 ns. Traditional methods of analysis, including gel electrophoresis or morphology assessment, revealed no significant differences among apoptotic subpopulations induced by treatment with these agents. Our data suggest that the mode of action of the various agents induces structural changes in chromatin organization that differentially alter accessibility of DNA to endonuclease digestion. Subsequent fluorescence lifetime analysis appears sensitive to the resulting differences in the residual chromatin in apoptotic cells following DNA cleavage. Results presented indicate that lifetime analysis, used in conjunction with conventional flow cytometry, can be useful for early detection of apoptosis-induced chromatin changes and may also potentially provide new information on the effects of different apoptosis-inducing agents.

Reduction in the radiation-induced late S phase and G2 blocks in HL-60 cell populations by amiloride, an efficient inhibitor of the Na+/H+ transporter.

Recent investigations that showed that amiloride delayed or inhibited apoptosis indicated it might also attenuate cell cycle checkpoints activated by ionizing radiation. In this report, single- and dual-parameter flow cytometry were used to investigate the effects of amiloride on cell cycle progression, and the effectiveness of amiloride to attenuate the S and G2 phase checkpoint responses induced by 2.5, 5.0, and 7.5 Gy of gamma radiation. The late S-phase delay, noted at 8 h following irradiation, and a radiation-induced G2 block, which was maximum at 16 h after irradiation, were both significantly reduced in amiloride-treated samples. Attenuation of the radiation-induced late S phase and G2 blocks resulted in cell division without apparent apoptosis or necrosis over a 24-h period. Results presented indicate that amiloride reduces the radiation-induced G2 block in HL-60 cell populations almost equally well as caffeine and to a greater extent than staurosporine. Immunofluorescent detection and quantitation of cyclin B1 expression demonstrated that amiloride only significantly reduced cyclin B1 expression following 5.0 Gy, when there was a notable induction of a significant G2 delay, followed by a relatively rapid recovery in cycling potential. The results suggest that amiloride affects the radiation-triggered signaling cascades to alter the kinase activity of proteins associated with mitotic progression, particularly the cyclin B1-p34cdc2 complex. Alternatively, alterations in intracellular ion concentrations induced by amiloride may lead to changes in Ca2+-dependent signaling cascades and thereby decrease the radiation-mediated cell cycle perturbations.

Flow cytometric fluorescence lifetime analysis of DNA-binding probes.

A new dimension has been added to multiparameter flow cytometric analysis through the recent development of techniques for rapidly measuring the fluorescence lifetime of probes bound to single cells. The lifetime measurements are made by phase-sensitive detection techniques in a flow cytometer (FCM) that also analyzes fluorescence intensity and other optical properties of stained cells. These lifetime assays have potential for elucidating the microenvironment of the interaction of fluorochrome probes and subcellular target molecules. Alterations in the lifetime of DNA probes have been observed in cells in different phases of the cell cycle, in different cell types, in differentiating cells, and in apoptotic cells with damaged chromatin. Lifetime differences noted also for intercalating dyes bound to DNA and dsRNA, indicated modifications in the modes of binding and provide the potential for analyzing both corformational states and nucleic acid metabolism. Future developments in the technology will provide multiple lifetime assays and thereby allow for detection and quantitation of selected subcellular probe-complexes with different lifetime signatures. These novel assays will expand the applications for quantitative studies on the binding of various chemical agents to DNA and other molecular targets in cells, and further improve methods for rapid screening of chemotherapeutic agents or environmentally toxic compounds.

Monitoring uptake of ellipticine and its fluorescence lifetime in relation to the cell cycle phase by flow cytometry.

Ellipticine (5,11-dimethyl-6H-pyrido[4,3-b]carbazole) is a green fluorescent plant alkaloid that inhibits DNA topoisomerase II activity and possesses pharmacologic activity toward both murine and human leukemias in vivo. In this flow cytometric study, the uptake of ellipticine was monitored as a function of cell volume and cell cycle phase in viable human promyelocytic (HL-60) cells costained with the DNA fluorochrome Hoechst 33342. Uptake of ellipticine was time and dose dependent; however, drug content was quantitatively similar in all phases of the cell cycle when normalized for DNA content or similar to cell size when correlated with cell volume. The fluorescence lifetime values of ellipticine in HL-60 cells, as analyzed by novel flow cytometric analysis, reached a plateau when the intra-cellular ellipticine intensity was still rising with increasing drug concentration. Since the free drug and the different subcellular ellipticine complexes, including DNA and RNA, had different lifetime values, the changes in the lifetime values appear to reflect differing proportions of unbound drug to that bound to different cellular constituents in the cells. Further development of phase-sensitive flow cytometry will provide for multiple lifetime determinations so that quantitation of drugs bound to the different cellular components can be performed along with the simultaneous determination of total drug uptake and cell cycle position. Such analyses should provide useful information for the design of drugs with greater affinity for cytotoxic targets.

Effects of heat stress on mouse testicular cells and sperm chromatin structure.

Scrotal regions of mice were exposed to a 38.0, 40.0, or 42.0 degrees C (+/-0.1) H2O bath for 60 minutes to determine the effects of elevated temperatures on testicular cells and sperm chromatin structure. Mice were killed on various days after exposure, and ratios of acridine orange-stained testicular cell populations were determined by flow cytometry. Testicular weights of mice exposed to 42.0 degrees C decreased significantly day 1 (P < 0.01) through 35 (P < 0.001). Also, a significant relative decrease in testicular haploid cells was seen on days 3-35 (P < 0.001) with a corresponding increase in the diploid population (P < 0.001). Testicular analyses of mice exposed to 38.0 degrees C were not significantly different from control values. Testis weights of mice exposed to 40.0 degrees C were not affected, but a relative decrease in percent haploid cells occurred on days 11 and 14 (P < 0.001). The sperm chromatin structure assay (SCSA) was used to measure the susceptibility of cauda epididymal sperm DNA to in situ denaturation at low pH. Caudal epididymides of mice exposed to 42.0 degrees C had no sperm. Caudal epididymal sperm from mice exposed to 40.0 degrees C were most susceptible to acid-induced DNA denaturation on days 3 (P < 0.05), 7, 11, and 14 (all P < 0.001). The 38.0 degrees C exposed mice showed some minor sperm chromatin abnormalities at later time points (days 11-35). When compared to sperm head morphology measurements, SCSA parameters were more sensitive indicators of heat-induced sperm abnormalities. These results show that mouse spermatogenesis is disrupted by scrotal exposure to environmental temperatures several degrees over normal physiological temperature and, of more biological interest, that some thermal ranges above normal allowed production of sperm with compromised nuclear chromatin structure.

New flow cytometric technologies for the 21st century.

The envelope that defines the limits within which flow cytometry was developed is being rapidly expanded. For example: detection sensitivity has been extended to single molecules, the size range of "particle" analysis now extends from DNA fragments to plankton (1,000.+ microns), cell and chromosome sorting rates are being increased dramatically by using inactivation procedures (50,000 per second versus 2,000 per second), rapid kinetic flow cytometry enables real-time analysis of molecular assembly and cell function in the sub-second time domain, the lifetime of a fluorochrome bound to a single cell can be measured with nsec precision, and classical karyotype information (cell to cell heterogeneity) can be determined in a flow based system. These frontiers have greatly expanded the range of new and exciting flow cytometric based biomedical applications. New enabling technologies have provided the means to measure DNA cleavage by the structure-specific nuclease, human Flap Endonuclease (FEN-1), in the 300 msec time frame. Phase sensitive measurements and fluorescence lifetime are proving to be major advances for understanding molecular environments that change with, for example, the process of apoptosis. The ability to detect single fluorescent molecules has been applied to the analysis of DNA fragments obtained from enzymatic digestion of lambda DNA. This technology is being used to rapidly and very accurately size DNA fragments for the human genome project. Optical chromosome selection is a faster, better, less complex approach to chromosome sorting. This method is based on the induction of specific damage to the DNA of selected chromosomes. Lastly, the miniaturization of a single cell fractionator has made it possible to perform single cell flow cytogenetics.

Differential effects of deuterium oxide on the fluorescence lifetimes and intensities of dyes with different modes of binding to DNA.

Deuterium oxide (D2O) increases both the fluorescence lifetime and the fluorescence intensity of the intercalating dyes propidium iodide (PI) and ethidium bromide (EB) when bound to nucleic acid structures. We have used spectroscopic analysis coupled with conventional and phase-sensitive flow cytometry to compare the alterations in intensity and lifetime of various DNA-binding fluorochromes bound to DNA and Chinese hamster ovary (CHO) cells in the presence of D2O vs phosphate-buffered saline (PBS). Spectroscopic and flow cytometric studies showed a differential enhancement of intensity and lifetime based on the mode of fluorochrome-DNA interaction. The fluorescence properties of intercalating probes, such as 7-aminoactinomycin D (7.AAD) and ethidium homodimer II (EthD II) were enhanced to the greatest degree, followed by the probes TOTO and YOYO, and the non-intercalating probes Hoechst 33342 (HO) and 4,6-diamidino-2-phenylindole (DAPI). The non-intercalating probe mithramycin (MI) gave unexpected results, showing a great enhancement of fluorescence intensity and lifetime in D2O, indicating that when staining is performed in PBS, much of the MI fluorescence is quenched by the solvent environment. Apoptotic subpopulations of HL-60 cells had a shorter lifetime compared to non-apoptotic subpopulations when stained with EthD II. These results indicate that accessibility of the dye molecules to the solvent environment once bound to DNA, leads to the differential enhancement effects of D2O on fluorescence intensity and lifetime of these probes.

Interactions of intercalating fluorochromes with DNA analyzed by conventional and fluorescence lifetime flow cytometry utilizing deuterium oxide.

Deuterium oxide (D2O) has been shown in previous studies to increase both the fluorescence lifetime and fluorescence intensity of propidium iodide (PI) and ethidium bromide (EB) when bound to nucleic acid structures. We have used spectroscopic analysis and conventional and phase-sensitive flow cytometry to compare changes in PI and EB fluorescence intensity and lifetime bound to DNA and fixed Chinese hamster ovary (CHO) cells in the presence of D2O vs. phosphate-buffered saline (PBS). Spectroscopic and flow cytometric studies showed a twofold enhancement of fluorescence intensity of PI and EB bound to fixed CHO cells in D2O and a 5 ns increase in PI and EB fluorescence lifetimes in D2O. The fluorescence lifetime of HL-60 cells stained with PI or EB was found to be 1-2 ns different from that of CHO cells, indicating that the lifetime of these fluorochromes is sensitive to chromatin configuration in different cells types. Apoptotic subpopulations of HL-60 cells had a significantly reduced fluorescence lifetime compared to nonapoptotic subpopulations. Results indicate that different chromatin states, or differences in the structures of PI and EB, lead to alterations in the fluorescence intensity and fluorescence lifetime of these intercalating probes.

Bull sperm head morphometry related to abnormal chromatin structure and fertility.

This study investigated the relationship between morphologically abnormal sperm, sperm chromatin structure, and fertility. Semen samples were obtained from 13 bulls. The sperm chromatin structure assay (SCSA), a sensitive measure of denaturability of sperm nuclear DNA in situ following acid treatment, was performed on each sample to quantitate abnormal chromatin structure. Feulgenstained sperm head morphology was measured by computerized image analysis (ONCOR-Image): Sixteen parameters were measured for each of 200 nuclei per sample. Fertility estimates were available for nine of the bulls. The SCSA variable SD alpha t was correlated with fertility ranking (r = 0.617, P < 0.01). No correlations were seen between means of the imaging variables and SCSA variables % COMP alpha t or SD alpha t. Significant correlations (P < 0.05) were seen between SD alpha t and the variation of imaging variables eccentricity, width, and light blobs. Significant correlations (P < 0.05) were seen between % COMP alpha t and the variation of imaging variables area, perimeter, p2a, bending energy, nmac, sphericity, eccentricity, length, and width. A regression model for fertility rankings incorporating the standard deviation of the imaging variables area, bending energy, nmac, eccentricity, condensity, light blobs, and dark blobs was highly significant (r2 = 0.999, P < 0.05). These results indicate that variation of morphometry measurements is likely a sensitive biomarker related to fertility potential and abnormal chromatin structure.

Effects of X-irradiation on mouse testicular cells and sperm chromatin structure.

The testicular regions of male mice were exposed to x-ray doses ranging from 0 to 400 rads. Forty days after exposure the mice were killed and the testes and cauda epididymal sperm removed surgically. Flow cytometric measurements of acridine orange stained testicular samples indicated a repopulation of testicular cell types following x-ray killing of stem cells. Cauda epididymal sperm were analyzed by the sperm chromatin structure assay (SCSA), a flow cytometric measurement of the susceptibility of the sperm nuclear DNA to in situ acid denaturation. The SCSA detected increased susceptibility to DNA denaturation in situ after 12.5 rads of x-ray exposure, with significant increases following 25 rads. Abnormal sperm head morphology was not significantly increased until the testes were exposed to 60 rads of x-rays. These data suggest that the SCSA is currently the most sensitive, non-invasive method of detecting x-ray damage to testicular stem spermatogonia.

Mammalian sperm DNA susceptibility to in situ denaturation associated with the presence of DNA strand breaks as measured by the terminal deoxynucleotidyl transferase assay.

Sperm from four mammalian species were analyzed by the sperm chromatin structure assay (SCSA) and the terminal deoxynucleotidyl transferase assay (TdTA) using flow cytometry. The SCSA quantitates the susceptibility of sperm nuclear DNA to in situ acid denaturation, while the TdTA quantitates the presence of endogenous DNA strand breaks in sperm nuclear chromatin. Correlations were seen between the percentage of sperm cells showing susceptibility to in situ acid denaturation and the percentage of cells showing the presence of DNA strand breaks for humans (r = 0.56, P = 0.004), rams (r = 0.84, P < 0.001), bulls (r = 0.78, P < 0.001), and stallions (r = 0.65, P < 0.001). No significant differences were seen when using fresh or frozen samples for either assay. These results suggest that sperm cells that are more susceptible to in situ DNA denaturation may have a greater number of accessible endogenous DNA strand breaks. We hypothesize that the DNA strand breaks produced in the normal transition from a somatic cell histone complex to a protamine complex are not ligated properly, resulting in residual DNA strand breaks and altered chromatin structure. Alternatively, altered chromatin structure could lead to the accessibility of the endogenous DNA strand breaks.