Validation of a flow cytometric acridine orange micronuclei methodology in rats.

Our laboratory has previously reported a flow cytometric acridine orange method for detection of micronucleus (MN) in the rat using cyclophosphamide as a test compound. To replace the manual method of scoring and satisfy Good Laboratory Practice (GLP) requirements, an extensive validation of the flow method was required. Therefore, manual scoring and flow cytometric determination of MN were compared using vincristine, chlorambucil, methotrexate, and doxorubicin compounds known to induce MN formation with various mechanisms of action. 1,2-Dimethylhydrazine (1,2-DH), a compound with negative or equivocal MN findings also was evaluated. The flow method consistently demonstrated dose- and time-dependent responses for MN production at all concentrations of vincristine, methotrexate, clorambucil, and doxorubicin. In contrast, manual scoring of slides failed to detect an increase in MN at the lowest doses of doxorubicin (1mg/kg) at 24 or 48 h, and methotrexate at 48 h, or any dose of methotrexate (50, 100, or 250 mg/kg) at 24h. Additionally, a dose-response for methotrexate at 48 h, and chlorambucil at 24 h were missed using manual scoring. For 1,2-DH, the flow method showed a low level (< 1.4-fold) increase in MN at all doses and times. In contrast, the manual method showed five-seven-fold increases at 24 h, but a < two-fold increase at 48 h in the highest dose only. These data may suggest that the flow method has a greater sensitivity and possibly accuracy than manual scoring. Significant decreases in polychromatic erythrocytes (PCE) were seen using both methods at approximately the same dose for all compounds. However, absolute flow cytometric PCE values were consistently higher than manual. Additional cytotoxicity parameters obtained by the flow method allowed a more complete assessment of cytotoxicity than PCE alone. Furthermore, data reported here combined with improved throughput, shortened data turnaround and reporting times, and possibly better precision due to evaluation of much larger numbers of cells clearly demonstrate the usefulness of flow cytometry method in the routine micronucleus evaluation.

Use of acridine orange in: flow cytometric assessment of micronuclei induction.

The micronucleus assay is a widely accepted method for evaluation of clastogens and aneugens. In the current study, acridine orange (AO) supravital staining was adapted for flow cytometric usage to assess micronucleated cells in rat bone marrow and spleen. Cyclophosphamide was used as a positive control test compound and results were compared to manual scoring in Wright-stained slides. In bone marrow, both manual and flow cytometric methods demonstrated positive dose response-trends for micronucleated polychromatic erythrocytes (MNPCE). Significant elevations in MNPCE were observed at all doses of cyclophosphamide, and comparisons between methods in bone marrow were not statistically different. The flow cytometric method was more sensitive in spleen samples, showing dose- and time-related increases in micronuclei compared with manual scoring. AO proved to be a sensitive discriminator of RNA and DNA, allowing distinct separation of polychromatic erythrocytes (PCE), normochromic erythrocytes (NCE), total nucleated cells (TNC), and micronucleated populations within both PCE and NCE regions. These results support the use of AO-based flow cytometry to provide a rapid and sensitive indicator of micronuclei inducers.

Use of acridine orange in: flow cytometric evaluation of erythropoietic cytotoxicity.

Cytotoxic insult to bone marrow frequently impairs the proliferating and maturational abilities of erythroid cells. Typically, a ratio of enucleated, immature polychromatic erythrocytes (PCE) to mature normochromatic erythrocytes (NCE) is used to assess cytotoxicity in the micronucleus (MN) assay. The effects of cyclophosphamide (CP) on PCE/NCE ratio in rat bone marrow and spleen were assessed by a newly developed flow cytometric procedure using glutaraldehyde-fixed, acridine orange (AO)-stained cells, and compared to manual scoring of PCE/NCE in Wright stained slides. Comparison of methods showed that manual and flow cytometric determination of PCE were not statistically different. Several other parameters of cytotoxicity could be simultaneously assessed because the method allowed use of unfractionated whole bone marrow/spleen cell samples. Absolute numbers of total nucleated cells (TNC), a ratio of TNC to total erythrocytes (TE), and determination of RNA content within the PCE population demonstrated dose- and time-dependent effects with CP treatment. Shifts in RNA content were particularly sensitive, correctly identifying all CP-treated from control specimens, even in those samples where PCE/NCE ratio was similar. The AO methodology provided a more rapid, statistically-superior, and thorough approach in the assessment of bone marrow and spleen cytotoxicity than the conventional manual method of scoring PCE/NCE ratio alone.

Genotoxicity evaluation of selenium sulfide in in vivo and in vivo/in vitro micronucleus and chromosome aberration assays.

Selenium monosulfide (SeS) was reported to be carcinogenic to livers of male and female rats and livers and lungs of female mice. However, its genotoxicity profile in short-term assays is somewhat equivocal. A multiple endpoint/multiple tissue approach to short-term genetic toxicity testing has been developed in our laboratory. In the present paper, the effect of SeS in in vivo and in vivo/in vitro micronucleus and chromosome aberration assays in rat bone marrow and spleen are reported. In the in vivo assay, small but statistically significant increases in bone marrow micronucleated polychromatic erythrocytes (MNPCEs) were observed 24 h after treatment of rats with 50 mg/kg SeS and 48 h after treatment with 12.5 mg/kg. A significant decrease in the PCE/total erythrocyte (TE) ratio, indicative of cytotoxicity, was observed at the 50 mg/kg dose at the 24-h timepoint. In spleen, no increases in MNPCEs or decreases in the PCE/TE ratios were observed. No evidence of a significant increase in aberrations was observed in bone marrow or spleen. In the in vivo/in vitro assay, no increase in micronucleated binucleated cells or cells with aberrations was observed in SeS-treated rats. The small but statistically significant increases in MN observed in the in vivo study are considered likely not to be biologically significant since no dose-response was observed and all the values obtained were within historical control range in our laboratory. Given the overall genetic toxicity profile of SeS, it appears that SeS may be a weak mutagen and that differences between testing protocols may be very important in determining whether or not it is found to be negative or positive. Histological evidence was obtained in this study that suggests that the liver is the acute target organ of SeS in rats. Given the fact that SeS is selectively hepatocarcinogenic, we are currently testing the hypothesis that the genotoxicity of SeS in rats may be more readily detectable in liver than in bone marrow or spleen.

An in vivo/in vitro method for assessing micronucleus and chromosome aberration induction in rat bone marrow and spleen. 1. Studies with cyclophosphamide.

The mouse micronucleus assay has long been used as an indicator of in vivo genotoxicity. Recently, it was shown that no single protocol is adequate to detect all clastogens. As a first step in developing a potentially more sensitive assay, micronucleus induction by cyclophosphamide (CP) was assessed in an in vivo/in vitro system using rat bone marrow and spleen cells. In each of two independent experiments, two rats/dose were treated i.p. with 0, 20, or 40 mg CP/kg and killed 6 h later. Cultures were then established in the presence of growth stimulants (interleukin-3 and granulocyte-macrophage colony stimulating factor for bone marrow; lipopolysaccharide and concanavalin A for spleen) and cytochalasin B, a cytokinesis inhibitor. Bone marrow cells were harvested and slides prepared 24 h after initiation, while spleen cells were harvested at 48 h. One thousand cells/tissue/group were scored for cell cycle kinetics and 1000 binucleate (BN) cells were scored for micronuclei. In addition, spleen cells were concurrently assayed for chromosome aberrations. A dose-related cell cycle delay was observed in both tissues in both experiments. Bone marrow showed a 6% average background frequency of micronucleated BN cells, while the low dose induced an average of 20%, and the high dose 31%. For spleen, the average control frequency of micronucleated BN cells was 3%, the low dose induced a 40% average frequency, and the high dose 65%. Also in splenocytes, a dose-dependent increase in chromosome aberrations was observed, with an almost 40-fold increase observed over the control value at the high dose. Thus, the in vivo/in vitro approach described here shows great potential in detecting drug induced genotoxicity. Also, spleen appears more sensitive than bone marrow to CP.

An in vivo/in vitro method for assessing micronucleus and chromosome aberration induction in rat bone marrow and spleen. 2. Studies with chlorambucil and mitomycin C.

An in vivo/in vitro system using rat bone marrow cells and spleen cells to assess micronucleus (MN) and structural chromosome aberrations (SCA) simultaneously (Moore et al., 1995) was further developed. In two separate experiments, two rats/dose/experiment were treated i.p. with 0, 5, 10 and 15 mg chlorambucil (CA)/kg or with mitomycin C (MMC) at 0, 1, 2, 4 mg/kg (experiment 1) or 0, 4, 6, and 8 mg/kg (experiment 2) and killed 6 h later. Cultures were then established in the presence of growth stimulants (interleukin-3 and granulocyte-macrophage colony stimulating factor for bone marrow; lipopolysaccharide and concanavalin A for spleen) and cytochalasin B, a cytokinesis inhibitor. Bone marrow cells were harvested 24 h after establishment of cultures, while spleen cells were harvested at 48 h. In addition, spleen cells were concurrently assayed for chromosome aberrations. With the MN endpoint, spleen cells appeared more sensitive than bone marrow cells to the effects of CA due both to a lower background and an increased response. For MMC, bone marrow cells exhibited both a higher background of MN and a greater numerical response than did spleen cells. However, on the basis of a fold-increase over control values, spleen cells were more sensitive than bone marrow cells. In general, the MN endpoint appeared more sensitive than the SCA in spleen cells after treatment with CA or MMC. Thus, the approach described here shows greater potential in detecting genotoxicity.

Inhibition of postbinding target cell lysis and of lymphokine-induced enhancement of human natural killer cell activity by in vitro exposure to ultraviolet B radiation.

In vitro exposure of human peripheral blood mononuclear cells (PBMC) to ultraviolet B (uvB) radiation has been shown to inhibit natural killer (NK) cell-mediated cytotoxicity in a dose-dependent fashion. The purpose of this study was to examine the manner by which uvB produced these deleterious effects. Inhibition of NK activity was not due to lethal injury to NK cells since the viability of cell populations enriched for NK activity was greater than 90% with the uvB doses employed. uvB appeared to directly affect NK cells since procedures which removed suppressor mechanisms, such as removal of monocytes and pharmacologic inhibition of the cyclooxygenase pathway, failed to reverse the response. Furthermore, no suppression of activity of unirradiated NK cells could be produced by coincubation of unirradiated NK cells with uv-irradiated NK cells. When the single cell assay for binding and killing was employed to determine at which stage in the lytic sequence inhibition occurred, it was found that binding was normal but lysis of bound targets and the recycling capacity of active NK cells were markedly reduced. At uvB doses above 50 J/m2, both interferon alpha (IFN-alpha) and interleukin 2 (IL-2) were ineffective in augmenting NK cell-mediated cytotoxic reactions after cells had been irradiated with uvB. Furthermore, incubation of NK cells with IFN-alpha prior to irradiation failed to protect against the inhibitory effects. These studies provide evidence that in vitro exposure of NK cells to uvB radiation inhibits their function by a direct nonlethal effect and that this inhibition occurs selectively at the postbinding stage of target cell lysis.