Nucleoside-mediated mitigation of 5-fluorouracil-induced toxicity in synchronized murine erythroleukemic cells.

5-Fluorouracil (5-FU) is a chemotherapeutic agent known to retard embryonic growth and induce cleft palate and limb deformities. The predominant mechanism underlying its toxic action is thought to be inhibition of thymidylate synthetase (TS), and hence thymidine triphosphate (dTTP) synthesis, resulting in alteration of the balance of deoxynucleotide (dNTP) pools and disruption of DNA synthesis. Indeed, previously we demonstrated retarded cell-cycle progression concurrent with a 60% decrease in TS activity in rat whole embryos following maternal exposure to 40 mg/kg 5-FU on Gestational Day 14 and in the murine erythroleukemic cell (MELC) suspension culture following exposure to 5-25 microM 5-FU for 2 hr. In the study described herein, we used high-performance liquid chromatography (HPLC) to demonstrate in both of these model systems that 5-FU exposure results in similar patterns of dNTP perturbations: a prolonged decrease in dTTP and dGTP levels and an increase in dCTP and dATP. In addition, we used centrifugal elutriation to synchronize MELC in the phases of the cell cycle (G0/G1 and early S) most sensitive to 5-FU to investigate the ability of nucleoside supplementation to mitigate 5-FU-induced toxicity. Our data indicate that following a 2-hr exposure to 5-25 microM 5-FU, supplementation with 1-10 microM thymidine (TdR) for 24 hr partially reverses 5-FU-induced toxicity as evidenced by increased cellular proliferation and cell-cycle progression and amelioration of 5-FU-induced perturbations of protein synthesis and cellular membrane permeability compared to unsupplemented 5-FU-exposed cells. However, TdR concentrations >/=100 microM inhibited growth or were cytotoxic. In comparison, supplementation with 10 microM-10 mM of deoxycytidine (CdR) was not toxic, but effected a dose-dependent recovery from 5-FU-induced toxicity. At 1-100 microM, neither deoxyadenosine nor deoxyguanosine supplementation reduced 5-FU-induced toxicity; at higher concentrations, both purine nucleotides inhibited cell growth. Although these results support the hypothesis that 5-FU disrupts the MELC cell cycle by depleting dTTP (a perturbation that is reversible by TdR supplementation), they also indicate that CdR supplementation offers an additional recovery pathway.

Factors affecting flow cytometric detection of apoptotic nuclei by DNA analysis.

Apoptotic thymocyte nuclei normally appear on a flow cytometric DNA histogram as a subdiploid peak. We observed that addition of a specific RNase A preparation to the detergent-based lysing buffer increased the fluorescence of toxicant-induced apoptotic nuclei to the level of untreated diploid nuclei. The chelating agent EDTA partially inhibited the RNase effect, suggesting contaminating divalent cations may have been involved. Moreover, spectrofluorometric analysis revealed that addition of RNase or divalent cations decreased the amount of DNA present in the lysate. This suggested that the upscale fluorescence shift was due to a decrease in the ability of the lysing buffer to extract DNA, possibly as a result of cation-induced chromatin condensation, rather than increased accessibility of fluorochrome binding sites due to apoptotic degeneration. Moreover, during a 16-h culture, we observed a similar, but time-dependent, upscale shift in the fluorescence of thymocytes undergoing apoptosis either spontaneously or as a result of exposure to 1 microM tributyltin methoxide (TBT), 2% ethanol, 2% methanol, or 1 microM dexamethasone phosphate (DEX). This commonality of effect suggests that a similar magnitude of chromatin reorganization occurs in apoptotic cells in prolonged culture regardless of the method of apoptotic induction. These findings should alert investigators to potential inaccuracies in the flow cytometric quantitation of apoptosis in in vitro systems employing prolonged toxicant exposures or complex lysing cocktails that may contain active contaminants.

Zinc deficiency causes apoptosis but not cell cycle alterations in organogenesis-stage rat embryos: effect of varying duration of deficiency.

Zinc deficiency is teratogenic in all species in which it has been examined. Zinc is an essential component of enzymes involved in DNA synthesis and cell proliferation, and may play an as yet undetermined role in apoptosis. To further our understanding of the role of zinc in normal development, we examined cell death and cell cycle parameters in embryos of pregnant rats fed a zinc-deficient diet for 2 to 10 days (0.5 microgram zinc/g diet; zinc-adequate diet was 25 micrograms zinc/g). To elucidate sensitive periods of development and susceptible cell populations, dams were fed the zinc-deficient diet from gestation day 1, 3, 7, or 9 and killed on day 11. Embryos were examined for morphology and developmental stage. From each litter, 2-3 embryos were stained with Nile blue sulfate (NBS) to visualize cell death, 3 embryos were frozen for flow cytometric cell cycle analysis and cell counts, and selected embryos were preserved for histological examination. Dams fed the zinc-deficient diet for more than 3 days reduced their food intake through gestation day 8 but increased food intake on day 9. Maternal plasma zinc dropped to 10-25% of control levels in the zinc-deficient groups. Zinc deficiency from gestation day 1 or 3 resulted in two categories of affected litters on day 11. One category had embryos which were morphologically normal but displayed extensive NBS staining in the visceral arches, neural tube, and somites. The second category had developmentally retarded or maldeveloped embryos which showed little NBS staining. Zinc deficiency from gestation day 7 produced cell death in the posterior dorsal midline in the area of premigratory neural crest cells, which was confirmed by histological examination. Zinc deficiency from gestation day 9 did not affect morphology or NBS staining. Percentages of cells in the G0/G1, S, and G2M phases of the cell cycle on gestation day 11, determined by flow cytometry, were similar to controls in all groups. This study shows that as few as 4 days of maternal zinc deficiency can produce excess embryonal cell death, and that neural crest cells may be particularly sensitive.

Biological modeling of 5-fluorouracil developmental toxicity.

A biologically-based dose-response (BBDR) model is a mathematical description of the biological events leading to expression of a toxic response. As an alternative to current approaches in non-cancer risk assessment, such models will reduce uncertainty in that they will provide a more comprehensive description of toxicity. We are involved in construction of a BBDR model for the developmental toxicity of 5-fluorouracil (5-FU) in the rat using multiple approaches. First, to identify critical events in the pathogenesis of 5-FU developmental toxicity, thymidylate synthetase (TS) inhibition and alterations in cell kinetics and growth were examined in embryos following maternal administration of 5-FU on day 14 of gestation. A dose-related decline in TS activity was observed within 1 h; however, maximal inhibition and recovery were similar at 10, 20 and 40 mg/kg. Dose-dependent cell cycle alterations were observed within 4 h after exposure and were maximal at 8 h. Hindlimb growth reduction was observed 24 h after exposure to 40 mg/kg, but not at lower doses. At term hindlimb defects were observed at doses above 30 mg/kg. An integrated dose-response model for hindlimb defects was derived from empirical relationships among these events. The resultant dose-response somewhat over-predicted the developmental toxicity of 5-FU, although results of a Monte Carlo simulation indicated that these data were not incompatible with model predictions. Overall, the results suggest that TS inhibition is a key component of the mechanism of 5-FU developmental toxicology, but the model does not capture all of the critical events in the induction of hindlimb defects. A preliminary mechanistic model for the inhibition of embryonic TS, DNA synthesis and cell cycle following maternal exposure to 5-FU, independently derived from literature data to further examine the potential role of this pathway in its developmental toxicity, predicted a dose-response for TS inhibition and DNA synthesis that closely reflected the observed patterns. These results further suggest that TS inhibition, resultant deficits in DNA synthesis and cell cycle perturbations represent a critical mechanistic pathway in the developmental toxicity of 5-FU.

Utility of fluorescence microscopy in embryonic/fetal topographical analysis.

For topographical analysis of developing embryos, investigators typically rely on scanning electron microscopy (SEM) to provide the surface detail not attainable with light microscopy. SEM is an expensive and time-consuming technique, however, and the preparation procedure may alter morphology and leave the specimen friable. We report that by using a high-resolution compound epifluorescence microscope with inexpensive low-power objectives and the fluorochrome acridine orange, we were able to obtain surface images of fixed or fresh whole rat embryos and fetal palates of considerably greater topographical detail than those obtained using routine light microscopy. Indeed the resulting high-resolution images afford not only superior qualitative documentation of morphological observations, but the capability for detailed morphometry via digitization and computer-assisted image analysis.

Flow cytometric detection of abnormal fetal erythropoiesis: application to 5-fluorouracil-induced anemia.

We sought to determine whether flow cytometric analysis of circulating fetal blood cells could be used to rapidly detect perturbations of fetal erythropoiesis. In addition, we wanted to determine whether this approach would allow sample collection by exsanguination instead of fetal cardiac puncture, a difficult technique used to prevent contamination of samples with maternal erythrocytes. To monitor fetal erythropoiesis from gestational day (GD) 14-20, we analyzed the cell size, RNA content, and percentage of circulating liver-derived reticulocytes relative to yolk-sac-derived erythroblasts. As a model toxicant, we chose 5-fluorouracil (5-FU), since we previously observed that maternal administration at 20-40 mg/kg on gestational day (GD) 14 produced fetal anemia on GD 16-17, as evidenced by dose-dependent decreases in the cell counts, hematocrit, and hemoglobin content of fetal blood obtained by cardiac puncture. We report herein that 48 hr after maternal 5-FU administration, both cardiac and peripheral blood samples exhibited a dose-dependent decrease in the relative percentage of reticulocytes, indicating a reduced rate of reticulocyte release from the fetal liver. Moreover, at 30 and 40 mg/kg, reticulocytes exhibited increased size and reduced RNA content on GD 16, but elevated RNA content (indicative of premature release) by GD 18. These data suggest that 5-FU inhibits both erythroid cell proliferation and RNA synthesis reversibly, resulting in an anemia that triggers compensatory release of immature reticulocytes.(ABSTRACT TRUNCATED AT 250 WORDS)

Cell death and cell cycle perturbation in the developmental toxicity of the demethylating agent, 5-aza-2'-deoxycytidine.

DNA methylation is a probable mechanism for regulating gene expression, and alterations in methylation may significantly affect embryonic development. We administered the cytidine analogue 5-aza-2'-deoxycytidine (dAZA), a specific and potent demethylator of DNA, to pregnant mice to determine its teratogenicity and effects on embryonic cell death and cell cycle. Groups of females were dosed intraperitoneally on gestation day 10 with doses of 0.05-3 mg/kg dAZA and killed at 4, 8, or 28 hr later. Two embryos per litter were immediately stained with Nile blue sulfate (NBS) to identify areas of cell death; the remaining embryos were frozen and stored for subsequent flow cytometric (FCM) analysis of the cellular DNA synthetic cycle in limb buds. A dose-related accumulation of cells in the S and G2/M phases was observed at 4 and 8 hr after maternal dosing. S-phase accumulation was the most sensitive indicator of effect; a dose-related increase in the percentage of hindlimb bud cells in S-phase was evident at all dosages 4 hr after maternal dosing. By 28 hr postdosing, a normal cell cycle phase distribution was observed at doses of < 0.3 mg/kg. However, cell cycle perturbations persisted at higher dosages. NBS staining demonstrated increased cell death in areas of rapid cell division, indicative of replication-associated cytotoxicity, at doses of > or = 0.1 mg/kg. Observation of litters from additional dams killed at term revealed that at dosages of > or = 0.3 mg/kg, cleft palate and hindlimb defects were significantly elevated. In addition, above 0.3 mg/kg, fetal weight was significantly decreased.(ABSTRACT TRUNCATED AT 250 WORDS)

Tributyltin and dexamethasone induce apoptosis in rat thymocytes by mutually antagonistic mechanisms.

The nuclei of apoptotic thymocytes can be identified by flow cytometry as a subpopulation exhibiting reduced DNA content. We observed that rat thymocyte cultures exposed to 1.0-2.5 microM tri-n-butyltin methoxide (TBT) exhibited a rapid time- and concentration-dependent induction of apoptosis, with > 85% of cells exhibiting reduced DNA content within 1 hr after exposure to 2.0-2.5 microM TBT. In contrast, exposure to 1.0 microM dexamethasone phosphate (DEX) resulted in a gradual time-dependent increase to approximately 45% induction of apoptosis by 6 hr versus approximately 15% spontaneous induction in controls. However, simultaneous exposure to TBT and DEX resulted in a decreased response: although TBT concentrations between 0.1 and 0.5 microM did not induce apoptosis, they reduced the ability of DEX to initiate apoptosis; while at TBT concentrations > or = 1.0 microM, simultaneous exposure to DEX substantially decreased the extent of TBT-induced apoptosis and cytotoxicity. Furthermore, while treatment with the protein synthesis inhibitor cycloheximide or the protein kinase C inhibitor H-7 completely blocked DEX-induced apoptosis, neither significantly reduced induction of apoptosis by TBT. Taken together, the toxicant-specific differences in the timing and extent of apoptotic induction and the dissimilar responses to CHX and H-7 suggest that TBT and DEX initiate endonuclease-mediated apoptotic cell death through different mechanisms. Moreover, the ability of each agent to retard the action of the other suggests that these mechanisms are directly or indirectly antagonistic.

Biologically based dose-response modeling in developmental toxicology: biochemical and cellular sequelae of 5-fluorouracil exposure in the developing rat.

Mechanistically based dose-response models for developmental toxicity require elucidation of critical biological events that intervene between maternal exposure and adverse developmental outcome. We have examined some of the major events in the rat embryo/fetus following a subcutaneous injection of 5-fluorouracil (5-FU; 0-40 mg/kg) to the dam on Day 14 of gestation. This treatment resulted in reduced fetal weight that was significant at doses of 20 mg/kg and higher, generalized reduced ossification at doses above 25 mg/kg, and wavy ribs at doses of 30 mg/kg and higher. Numerous malformations including cleft palate and hindlimb defects were substantially increased at doses of 35 and 40 mg/kg. 5-FU inhibits thymidylate synthetase (TS), resulting in inhibited growth of rapidly proliferating tissues. To identify early events in the pathogenesis of hindlimb defects, we examined the effects of 5-FU on TS activity, cell cycle, growth, and morphology in the developing hindlimb as a function of dose and time. The rate of decline of TS activity following 5-FU exposure was dose related, although maximal inhibition and recovery were similar at doses within (20 and 40 mg/kg) and below (10 mg/kg) the range of detectable developmental toxicity. Flow cytometric analysis of nuclei from embryonic hindlimbs revealed a transient increase in the percentage of cells in S phase and decrease in G0/G1 phase 8 hr after maternal injection of 20-40 mg 5-FU/kg, but not at lower doses. Reduction in growth and morphometric changes of hindlimbs were observed only after maternal exposure to 40 mg/kg. The tissue specificity of these effects was examined by comparing the hindlimb with other embryonic tissues. There was also a dose-related decline of TS activity in the embryonic liver. However, the pattern of recovery of TS activity and cell cycle alterations were different in the liver than in the hindlimb, probably reflecting the higher cell proliferative rate in the liver at this stage. We have derived a quantitative, empirical model for induction of hindlimb defects based on TS inhibition and subsequent cellular events following 5-FU exposure. The model predicted a dose response similar to that of the observed data although the predicted curve was shifted toward lower doses. These results suggest that while this model may not capture all of the critical events involved in the induction of hindlimb defects following maternal exposure to 5-FU, it does reflect a central mechanism of its developmental toxicity.(ABSTRACT TRUNCATED AT 400 WORDS)

Fetal anemia following maternal exposure to 5-fluorouracil in the rat.

Previous studies from our laboratory have shown that maternal 5-fluorouracil (5-FU) exposure on day 14 of gestation (GD14) in the rat results in dose-dependent retardation of both cell cycle progression and growth of embryonic liver. At this developmental stage, hepatic erythropoiesis is the primary source of new circulating fetal erythrocytes. This study examined dose-dependent hematological changes in the fetus after maternal 5-FU exposure (0, 20, 30, 40 mg/kg on GD14) to assess 1) hematopoiesis as a potential target for 5-FU developmental toxicity and 2) the role of the observed 5-FU-induced fetal anemia in adverse developmental outcome. Standard clinical hematological parameters, including hematocrit, hemoglobin content, and erythrocyte counts, were measured in fetal blood drawn by cardiac puncture. Dose-related deficits were observed in all of these parameters within 48 hr of 5-FU administration. Calculation of various red cell indices revealed a concomitant increase in mean cell volume and mean cell hemoglobin. These changes were preceded by depletion of hepatic precursor populations which was evident by 24 hr after maternal exposure to 30 or 40 mg/kg. At doses of 20 and 30 mg/kg there was full and moderate recovery, respectively, in these endpoints by 72 hr after dosing, but persistent deficits were observed at 40 mg/kg. Fluorescence microscopy of Höechst-stained fetal blood smears revealed that at both 48 and 72 hr after dosing, the proportion of nucleated yolk sac-derived erythrocytes was increased relative to control.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparison of cellular and nuclear flow cytometric techniques for discriminating apoptotic subpopulations.

We compared cellular flow cytometric methods employing carboxyfluorescein (CF), Höechst 33342, and Höechst 33258 with a nuclear method in their ability to discriminate apoptotic subpopulations in rat thymocyte cultures exposed to dexamethasone or tributyltin. In the nuclear technique, apoptotic cells appeared as a single population containing reduced DNA content, while in the cellular techniques, apoptotic cells appeared as two or more subpopulations exhibiting increased fluorescence. Of these subpopulations, early apoptotic cells [which excluded propidium iodide (PI), indicating maintenance of membrane integrity] exhibited higher fluorescence but the same level of axial light loss (i.e., size/refractive index) as viable cells; late apoptotic and dead cells (which incorporated PI) exhibited decreased axial light loss. However, while the Höechst dyes allowed discrimination of late apoptotic from dead cells, CF did not. In comparing sensitivity to staining conditions, Höechst 33258 fluorescence was the most stable over time, Höechst 33342 the least, and CF fluorescence not only varied with time, but with tri-n-butyltin methoxide concentration. Comparison of single-parameter analyses revealed that axial light loss was sensitive only to late apoptotic changes; nuclear fluorescence was a better indicator of apoptotic subpopulations, but still underestimated the total percentage of affected cells, and Höechst 33342 distinguished early apoptotic cells as those with elevated fluorescence. Early apoptotic cells stained with Höechst 33258 also exhibited increased fluorescence, but could not be distinguished from late apoptotic and dead cells without a second parameter. These findings indicate that of the methods investigated, the method of choice for detecting apoptosis depends on the goal of analysis: Höechst 33258 was best for discriminating apoptotic subpopulations, and CF was best for assessing alterations of membrane fluidity. For single-parameter analyses, Höechst 33258 was best for determining the total percentage of affected cells, while Höechst 33342 could be used to determine the percentage in early apoptosis.

Effects of developmental stage and tissue type on embryo/fetal DNA distributions and 5-fluorouracil-induced cell-cycle perturbations.

Cell-cycle analysis of nuclei obtained from the circulating erythroblasts (gestational day [GD] 11-16), livers (GD 14-19), and whole embryos (GD 10-13) or remaining (extrahepatic) tissues (GD 14-16) of rat embryos/fetuses revealed age- and tissue-dependent variations in the relative percentages of cells in the G0/G1, S, and G2/M phases of the cell cycle. With development, the rate of cell proliferation declined resulting in decreases in the relative percentage of S-phase cells and increases in the G0/G1 percentage, while the percentage of G2/M-phase cells remained relatively constant. Comparing tissue cell-cycle profiles during development, erythroblasts exhibited the most rapid age-dependent decline in S-phase percentage (from 75% at GD 11 to 8% by GD 14), embryos/extrahepatic tissues exhibited a more gradual reduction (from 55% at GD 10 to 14% by GD 15), while the hepatic isolates exhibited a relatively constant S-phase percentage of approximately 40% from GD 14 to GD 18 before decreasing to 23% at GD 19. These age-dependent variations suggest that cell-cycle distribution may be useful in staging embryogenesis and in detecting abnormal development. To determine how these developmental and organ-specific cell-cycle variations affect toxic response, we sampled GD 11-13 embryos 6 hr after maternal administration of a teratogenic dose of 5-fluorouracil (5-FU), a thymidylate synthetase inhibitor that induces S-phase accumulation. The results indicate that, on a relative basis, the amount of induced S-phase accumulation in erythroblasts and whole embryos 6 hr postdosing increased with development.(ABSTRACT TRUNCATED AT 250 WORDS)

Utility of the murine erythroleukemic cell (MELC) in assessing mechanisms of action of DNA-active developmental toxicants: application to 5-fluorouracil.

Murine erythroleukemic cells (MELC) exposed to 2'-deoxy-5-azacytidine (D-AZA) or to the active cyclophosphamide (CP) metabolites phosphoramide mustard (PAM) and 4-hydroxycyclophosphamide (OHCP) exhibit cell-cycle perturbations similar to those seen in limb bud nuclei of gestational day (GD) 10 CD-1 mouse embryos exposed in utero to D-AZA or CP, respectively. The similarities in response suggest MELC may be a useful model for determining mechanisms of action of DNA-active developmental toxicants. As such, we used the MELC model to investigate the mechanism of action of 5-fluorouracil (5-FU), an antimetabolite that induced in GD 14 rat fetuses an apparent S-phase accumulation in limb cells 8 hr after in utero exposure, but S-phase depletion in liver cells 24 hr postexposure. MELC timed-recovery and synchronization studies suggest that in proliferative tissues, 5-FU induces an early S-phase accumulation, followed by a synchronous, concentration-dependent delay in progression through the cell cycle. Consequently, it is the tissue-specific rate of delay, rather than different mechanisms of action, that results in apparent tissue-specific perturbations. Moreover, growth and cell-cycle data suggest that cells entering S phase (when TS activity is greatest) are the most sensitive to 5-FU toxicity. Assays of the TS activity of recovering MELC reveal that although the initial extent of TS inhibition does not appear to be concentration-dependent, the time to recovery is, suggesting that the rate of S-phase progression is closely associated with TS activity. Together, the induction of similar cell-cycle perturbations in embryonic/fetal tissues and MELC following exposure to CP (or CP metabolites), D-AZA, or 5-FU, as well as the adaptability of MELC to a variety of kinetic assays suggests that, for those developmental toxicants suspected of inducing cell-cycle perturbations in embryonic/fetal tissues, MELC may prove useful for elucidating mechanisms of action.

Effects of 5-fluorouracil on embryonic rat palate in vitro: fusion in the absence of proliferation.

5-Fluorouracil (5-FU) inhibits the enzyme thymidylate synthetase (TS) which results in inhibition of DNA synthesis. 5-FU is teratogenic in many species, inducing cleft palate, limb, and tail defects. In the present study, gestation day (GD) 14 embryonic rat craniofacial explants were exposed to 5-FU in organ culture with increasing concentrations and durations of exposure. Palates exposed to 5-FU were morphologically abnormal and craniofacial shape, size, and palatal fusion pattern were affected with the severity of effects dependent on concentration and duration of exposure. Cleft palate was induced in vitro as opposing palates overlapped in a narrowed oral cavity. Palates exposed to higher levels of 5-FU were growth inhibited, but fused even though proliferation ceased and few cells were available to participate in elevation and fusion. This was demonstrated as a biphasic concentration-response profile for palatal fusion in which 0.05 to 0.15 micrograms 5-FU/ml produced decreasing rates of palatal fusion, while exposure to 0.15 to 3.0 micrograms/ml resulted in progressively increasing rates of fusion. The effects of 5-FU were detected biochemically as a reduction in TS activity which was concentration and time dependent during the first 12 hours, with a return to control levels by 24 hours. During the first day, 5-FU did not alter protein levels, but DNA levels significantly decreased at the high concentration, 2.0 micrograms/ml. After 5 days in culture, both DNA and protein decreased with increasing 5-FU concentration and duration of exposure. Also by the end of the culture period, 3H-TdR incorporation had decreased in a concentration dependent manner. It is concluded that progressive inhibition of proliferation and growth in organ culture results in two different morphological outcomes: cleft palate resulting from a narrowed oral cavity and increased incidence of anterior palatal fusion under conditions of strong growth reduction. This study demonstrates that elevation and fusion can occur in the absence of growth and proliferation. Based on these observations, severe inhibition of growth or proliferation would not necessarily be sufficient to induce cleft palate.

An efficient multiple-exposure analysis of the toxicity of crisnatol, a DNA intercalator in phase II clinical trials.

To investigate the toxicity and mechanism of action of crisnatol (CRS), a new DNA intercalator currently in phase II clinical trials, we analyzed cellular and nuclear flow cytometric (FCM) parameters of murine erythroleukemic cells (MELC) exposed to a range of CRS concentrations over three exposure conditions: short-term (4 h), long-term (24 h), and short-term with recovery (4 h+/19 h-). At 0.5-1.0 microM CRS, 4 h exposure results in a reversible G2-phase block, while 24 h exposure results in greater than G2 polyploidy. At 5-10 microM CRS concentrations, cells exhibit persistent retardation of S-phase progression or irreversible G2 and/or greater than G2 blocks, depending on duration of exposure. Cells terminally blocked in G2 exhibit increased nuclear/cellular volumes and increased nuclear fluorescein isothiocyanate (protein) staining, suggestive of unbalanced growth. At 25-50 microM CRS concentrations, MELC exhibit severe membrane perturbation (loss of viability) regardless of exposure. In contrast, following similar exposures to an inactive isomer of CRS, MELC exhibit minimal cell cycle effects, suggesting that cell cycle kinetics may be a useful criterion for assessing potential efficacy. Similar analyses with different classes of chemotherapeutic agents reveal that the range of induced cellular/nuclear perturbations varies with the class of compound used. Taken together, these results suggest that drug toxicity can vary with both concentration and duration of exposure and, as such, a selective multiple-exposure FCM analysis may better represent the spectrum of drug action for drug development and pharmacodynamic studies.

The reversibility of tributyltin-induced toxicity in vitro as a function of concentration and duration of exposure (C x T).

The toxicity exhibited by murine erythroleukemic cells (MELC) exposed to tributyltin (TBT) is a function of both concentration (C) and duration of exposure (T). At or above a critical C x T product value (CPV) (e.g., 0.5-1.0 microM TBT, 6 hr), exposed MELC exhibit severe, irreversible toxicity: decreased membrane integrity (viability, measured by propidium iodide [PI] exclusion), grossly perturbed cell-cycle distributions, and fixation of the plasma membrane/cytoplasm complex. Below the CPV, exposed cells exhibit retention of carboxyfluorescein (CF) fluorescence (indicative of decreased plasma membrane permeability) and decreased cell proliferation, a result of retardation of progression into, through, and out of the S (DNA synthetic) phase of the cell cycle. However, following washout and recovery, mean CF fluorescence, cell proliferative capacity, and cell-cycle kinetics return to control levels. These results suggest that the toxic changes induced by TBT exposure may be reversible if exposure conditions do not exceed the CPV. To assess whether the CPV has been exceeded, a multiparameter flow cytometric analysis of membrane integrity and cell-cycle kinetics is useful.

Utility of light scatter in the morphological analysis of sperm.

We were able to differentiate the morphologically diverse sperm nuclei of four animal species by using an Ortho flow cytometer to detect the forward light scatter from a red (helium-neon) laser. Cytograms depicting the axial light loss and forward red scatter signals revealed unique, but reproducible, sigmoid distributions that reflected not only interspecies differences in shape and size, but variations in particle refractive index and orientation within the flow cell at the time of analysis. Consequently, we were able to use regional gating of the light scatter cytogram to minimize the influence of orientation on the resolution of the fluorescence signal. We also observed that sperm enlarging as a result of chemically induced decondensation exhibit over time a biphasic shift (increase, then decrease) in light scatter at a species-dependent rate. These results suggest that, without any special adaptations to the flow cytometer, light-scatter parameters can be used to discriminate morphologically different sperm, to enhance the resolution of fluorescence measurements that may otherwise be confounded by variability in radial orientation, and to detect alterations in the rate of a biochemical/biophysical process such as decondensation.

In vitro/in vivo comparison of yolk-sac function and embryo development.

The yolk-sac function and development of rat embryos grown in vitro for 24 hr, starting on day 10.5, were compared with those of embryos grown in utero. The embryos grown in vitro had significantly fewer somites, shorter crown-rump length and smaller yolk-sac diameter when compared with the embryos grown in vivo but all values were within the normal range for this stage of gestation. Head length was not significantly different between the two groups. The cellular and nuclear volumes (Coulter counter) of nucleated yolk-sac red blood cells did not differ significantly between the two groups. RBC cell-cycle analyses by flow cytometry did not reveal any difference between in vitro and in vivo embryos. The clinical chemistries of embryo-yolk-sac homogenates were compared. Protein, triglyceride, lactate dehydrogenase, cholesterol, urea nitrogen and glutamic-oxalacetic transaminase concentrations did not differ significantly between the two groups. The in vitro embryos had significantly lower gamma-glutamyl transferase (GGT) and sorbitol dehydrogenase activities. GGT activity is almost entirely in the yolk sac in the day 10.5 conceptus. alpha-Foetoprotein is synthesized by the yolk sac at this stage of development and was significantly lower in the in vitro embryos. Transferrin is transported across the yolk sac to the embryo and was significantly higher in the in vitro embryos. These data indicate that impaired yolk-sac function could, in part, be responsible for the developmental delays and the short survival times of cultured embryos.

Polyploidy induction as a consequence of topoisomerase inhibition. A flow cytometric assessment.

Following recovery from a 4-hr exposure to clinically achievable concentrations of the topoisomerase II inhibitors Adriamycin, teniposide, or amsacrine or the putative topoisomerase II inhibitor crisnatol, murine erythroleukemic cells remained viable for up to 48 hr, but did not proliferate. Cell cycle analysis after a 24-hr recovery revealed blocks in G2 (4N DNA) or greater than G2 (up to 8N DNA) polyploid stages. The relative percentages of cells in either stage was a function of drug concentration and cell cycle stage at time of exposure: typically, cells exposed during S phase became blocked in G2, whereas those exposed during G2/M progressed into greater than G2 polyploid stages. G2-blocked cells exhibited a 2- to 3-fold increase in nuclear protein content and cellular/nuclear volume (i.e. unbalanced growth) and approximately 5% more DNA stainability (as a consequence of nuclear conformational changes rather than redundant DNA synthesis). In all cases, at the drug concentrations studied, mitotic figures were absent and G2 and greater than G2 blocks were irreversible, indicating that the mechanism of polyploidy induction differs from that of microtubule inhibitors. These findings suggest that although topoisomerase inhibitors interfere with DNA synthesis in the S phase, their induction of greater than G2 polyploid blocks may involve direct or indirect inhibition of chromosome condensation.

A new action for topoisomerase inhibitors.

Topoisomerases are known to aid DNA replication by breaking and resealing supercoiled DNA. Consequently, cells exposed to topoisomerase inhibitors before or during the S (DNA synthetic) phase of the cell cycle undergo abnormal DNA replication and become irreversibly blocked in the G2 (pre-mitosis) phase. We report that following a 4-h exposure to topoisomerase II inhibitors, murine erythroleukemic cells (MELC) do not form mitotic figures but exhibit a time-dependent progression into G2 (4N DNA) and greater than G2 (up to 8N DNA) stages of the cell cycle. Following exposure to the topoisomerase I inhibitor camptothecin, recovering MELC also exhibit greater than G2 polyploidy, but to a considerably lesser degree: mitotic figures are present and a subpopulation of cells resumes cycling. However, both topo I and topo II inhibitors induce maximal percentages of greater than G2 cells when synchronized MELC are in the G2/M phase at the time of exposure. This suggests that, in addition to their S-phase action, topoisomerase inhibitors can interfere with chromosome condensation during G2 and, in so doing, induce polyploidy.