Induction of micronuclei and anaphase aberrations by cytochalasin B in human lymphocyte cultures

The frequency of micronucleated cells in isolated 72-h human lymphocyte cultures treated with cytochalasin B (Cyt-B; 1.5-6 micrograms/ml for the last 28 h) was 9-21 times higher (mean 14.6 times) among multinucleate than binucleate cells. At 3 micrograms/ml, the concentration of Cyt-B originally recommended for the human lymphocyte micronucleus assay, the frequency of micronucleated multinucleate cells was 8.5%, while 0.7% of the binucleate cells had a micronucleus. Although no dose-dependent induction of micronuclei could be observed for either of the cell types, increase in the concentration of Cyt-B was associated with a decrease in the ratio of multinucleate to binucleate cells. Treatment with Cyt-B (1.5-12 micrograms/ml) increased the frequency of anaphase cells with aberrations, especially lagging chromatids. This finding was explained by a dose-dependent increase in multipolar (greater than or equal to 3 poles) divisions which had a high frequency of anaphase aberrations (39-53%), irrespective of the concentration of Cyt-B. Bipolar anaphases did not show a significant increase in aberrant cells, although a suggestive dependence on the concentration of Cyt-B was observed. The findings indicate that the high frequency of micronuclei in multinucleate lymphocytes produced by Cyt-B is due to mitotic errors arising when bi- (and multi-) nuclear cells divide. To avoid possible artifactually high micronucleus frequencies due to inclusion of cells that have divided greater than or equal to 2 times in the presence of Cyt-B, it is recommended that, in the human lymphocyte micronucleus assay using the cytokinesis-block method, the cell culture time is reduced to minimize the frequency of such cells and that only good preparations and regularly shaped binucleates are included in the analysis.     

Chromosomal damage and mutations after exposure of Chinese hamster cells to high concentrations of oxygen

Chinese hamster lung fibroblast cells (V 79—379 A) were grown as monolayers and exposed to various concentrations of oxygen ranging from 40 to 95% at atmospheric pressure, for periods from 6 to 96 h. There were many abnormalities among stained cells on slides, including binucleate and multinucleate cells and micronuclei. The nuclei of stained mitotic cells, expanded by hypotonic solution, contained much chromosomal damage. This damage consisted chiefly of gaps and breaks in the chromatids and it increased in a dose-related manner with both percentage of oxygen and duration of exposure, reaching 100% of nuclei after 72 h exposure to 95% oxygen. Growth rate and survival of the cells were much reduced and colony-forming ability was inhibited to about 50% by a 24-h exposure to 95% oxygen and fell to less than 1% after 48 h at this oxygen tension. Mutations to azaquanine resistance were observed after exposure of hamster cells to 60, 80 and 95% oxygen for 24 or 48 h and also for 72 h in the case of 60% oxygen. The highest mutant frequency observed was 250 per 10⁶ surviving cells (mean control 8.2).     

Chromosomal damage and mutations after exposure of chinese hamster cells to high concentrations of oxygen

Chinese hamster lung fibroblast cells (V 79–379 A) were grown as monolayers and exposed to various concentrations of oxygen ranging from 40 to 95% at atmospheric pressure, for periods from 6 to 96 h. There were many abnormalities among stained cells on slides, including binucleate and multinucleate cells and micronuclei. The nuclei of stained mitotic cells, expanded by hypotonic solution, contained much chromosomal damage. This damage consisted chiefly of gaps and breaks in the chromatids and it increased in a dose-related manner with both percentage of oxygen and duration of exposure, reaching 100% of nuclei after 72 h exposure to 95% oxygen. Growth rate and survival of the cells were much reduced and colony-forming ability was inhibited to about 50% by a 24-h exposure to 95% oxygen and fell to less than 1% after 48 h at this oxygen tension. Mutations to azaguanine resistance were observed after exposure of hamster cells to 60, 80 and 95% oxygen for 24 or 48 h and also for 72 h in the case of 60% oxygen. The highest mutant frequency observed was 250 per 10⁶ surviving cells (mean control 8.2).     

Cytogenetic analysis of nasal mucosa cells and lymphocytes from high-level long-term formaldehyde exposed workers and low-level short-term exposed waiters

The evidence for genotoxic potential of formaldehyde (FA) in humans is insufficient and conflicting. We previously reported a higher frequency of micronuclei in nasal and oral exfoliative cells from students exposed to formaldehyde vapor for short-term. To further evaluate the genetic effects of long-term occupational exposure to FA and short-term exposure to FA of indoor sources, the frequencies of micronuclei (MN) in nasal mucosa cells, sister chromatid exchanges (SCEs) of peripheral lymphocytes, and the lymphocyte subsets were evaluated in 18 non-smoking workers (mean exposure duration was 8.6 years) in an FA factory and 16 non-smoking waiters exposed to FA for 12 weeks in a ballroom. A non-smoking student group without occupational exposure (n=23) to FA was used as control. The 8h time-weighted average (TWA) concentrations of formaldehyde was 0.985+/-0.286 mg/m3 with the ceiling exposure concentration of 1.694 mg/m3 in the workshop, and 0.107+/-0.067 mg/m3 in the ballroom (5 h TWA). Higher frequencies of micronuclei per thousand cells in nasal mucosa cells of workers versus control (2.70+/-1.50 versus 1.25+/-0.65, p<0.05) and higher frequency of SCEs in peripheral lymphocytes of workers group (8.24+/-0.89 versus 6.38+/-0.41, p<0.05) were observed. Increased frequency of micronuclei in nasal mucosa cells or SCE in peripheral lymphocytes was not found among waiters group. The results suggest that the genotoxic potential of high level FA exposure may have occupational risks in long-term exposure groups.     

Multicolour FISH in an analysis of chromosome aberrations induced by N-nitroso-N-methylurea and maleic hydrazide in barley cells

The present study is a rare example of a detailed characterization of chromosomal aberrations by identification of individual chromosomes (or chromosome arms) involved in their formation in plant cells by using fluorescent in situ hybridization (FISH). In addition, the first application of more than 2 DNA probes in FISH experiments in order to analyse chromosomal aberrations in plant cells is presented. Simultaneous FISH with 5S and 25S rDNA and, after reprobing of preparations, telomeric and centromeric DNA sequences as probes, were used to compare the cytogenetic effects of 2 chemical mutagens: N-nitroso-N-methylurea (MNU) and maleic hydrazide (MH) on root tip meristem cells of Hordeum vulgare (2n=14). The micronucleus (MN) test combined with FISH allowed the quantitative analysis of the involvement of specific chromosome fragments in micronuclei formation and thus enabled the possible origin of mutagen-induced micronuclei to be explained. Terminal deletions were most frequently caused by MH and MNU. The analysis of the frequency of micronuclei with signals of the investigated DNA probes showed differences between the frequency of MH- and MNU-induced micronuclei with specific signals. The micronuclei with 2 signals, telomeric DNA and rDNA (5S and/or 25S rDNA), were the most frequently observed in the case of both mutagens, but with a higher frequency after treatment with MH (46%) than MNU (37%). Also, 10% of MH-induced micronuclei were characterized by the presence of only telomere DNA sequences, whereas there were almost 3-fold more in the case of MNU-induced micronuclei (28%). Additionally, by using FISH with the same probes, an attempt was made to identify the origin of chromosome fragments in mitotic anaphase.     

Effect of various concentrations of acyclovir on cell survival and micronuclei induction on cultured HeLa cells

The HeLa cells were treated with 0, 0.01, 0.1, 1, 10 and 100 μM acyclovir (ACV) for 8 h duration and the growth kinetics, cell survival and micronuclei induction were determined. Treatment of HeLa cells with various concentrations of ACV resulted in a concentration-dependent decline in growth kinetics, cell proliferation indices and cell survival. ACV, 100 μM, completely inhibited cell division, where no appreciable changes in cell number were observed from 1 to 5 days post-treatment. This is reflected in cell survival, where the surviving fraction of cells was reduced to 1/2 at 100 μM ACV. Conversely, the frequency of micronuclei showed a concentration-dependent elevation at 20, 30 and 40 h post-treatment. ACV not only induced one micronuclei-bearing binucleate cell but also binucleate cells bearing two and multiple micronuclei in a concentration-dependent manner. The micronuclei frequency increased with time up to 30 h post-treatment and declined thereafter. The relationship between micronuclei induction and cell survival was determined by plotting the former on Y- and the latter on X-axes, respectively. The surviving fraction of cells declined with the elevation in micronuclei frequency and a best fit was observed for linear quadratic formalism.     

A quantitative cytochemical investigation of osteoclasts and multinucleate giant cells

Summary Quantitative cytochemical, immunocytochemical, autoradiographic and electron cytochemical investigations have been used to compare osteoclasts with multinucleate giant cells that had been freshly obtained from the same animal. The levels of -acid galactosidase activity, the DNA in individual nuclei and the cellular protein content were similar in both cell types. However, osteoclasts generally possessed greater acid phosphatase and NADH dehydrogenase activity but lower levels of fluoride-inhibited non-specific esterase activity than multinucleate giant cells. The acid phosphatase activity in multinucleate giant cells was completely inhibited by 100 mM tartrate, but in osteoclasts only a 20% reduction in activity was observed. Formation of multinucleate giant cells in a bone microenvironment (thin bone slices) did not increase their content of tartrate-resistant acid phosphatase activity. Moreover, in osteoclasts, endogenous peroxidase activity was undetectable but present in several granules within the cytoplasm of multinucleate giant cells. Osteoclasts and multinucleate giant cells displayed a similar microtubular distribution, but calcitonin, which induced rearrangement of microtubules and cellular contraction in osteoclasts, had no effect on multinucleate giant cells. Thus, these investigations reveal both similarities and differences between these two syncytia and support the hypothesis that osteoclasts and multinucleate giant cells are related. Possibly osteoclasts arise from monocyte progenitors before commitment to a macrophage lineage has occurred.     

Fabrication and growth mechanism of ZnO nanostructures and their cytotoxic effect on human brain tumor U87, cervical cancer HeLa,and normal HEK cells

ZnO nanostructures of diverse shape were grown via a solution process with different precursors and conditions. Morphological investigation of the nanostructures was carried out using field emission scanning electron microscopy and transmission microscopy observations and revealed that the nanostructures exhibit a wurtzite phase with an ideal lattice fringe distance of approximately 0.52 nm. The powder crystallinity was examined via X-ray diffraction spectroscopy. Screening results from anticancer studies of the effects on human brain tumor U87, cervical cancer HeLa, and normal HEK cells of ZnO nanostructures of diverse shape were obtained and indicate promising activity that varies with changes in the structure and the size of the particles. Treatment-induced cell death [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide and survival assay], growth inhibition, cytogenetic damage (formation of micronuclei), and apoptosis were studied as parameters for the cellular response. Treatment with nanostructures enhanced growth inhibition and cell death in a concentration-dependent manner in both U87 and HeLa cell lines. At higher concentrations (above 15.6 μg/ml) the cytotoxic effects of the nanoparticles were highly synergistic and mainly mediated through apoptosis, implying the possible interactions of lesions caused by the agents. The enhanced cell death due to nanoparticles was accompanied by a significant increase (2–3 fold at 31.25 μg/ml) in the formation of micronuclei in U87 cells. The increase in the formation of micronuclei observed after treatment indicates that these structures may interfere with the rejoining of DNA strand breaks. Among all the nanostructures, nanoparticles and sheets exhibited potent activity against both HeLa and U87 cells. However, despite potent in vitro activity, all nanostructures exhibited diminished cytotoxicity against normal human HEK cells at all effective concentrations.     

Polyamine starvation causes parallel increase in nuclear and chromosomal aberrations in a polyamine-dependent strain of CHO

Deprivation of polyamines and ornithine causes in a polyamine-dependent CHO strain aneuploidy and alterations in nuclear morphology including micronuclei, macronuclei, framented and bulged nuclei. There is also formation of multinucleate cells. The number of micronuclei and certain other nuclear aberrations increase concomitantly with chromosome abberrations.     

Multinucleate plant cells: I. Aneuploidy in a proliferating population

A new method for the production of multinucleate plant cells in meristematic populations is described. This method involves the aneuploidy induction of nuclei of a same cell. Allium cepa root tips were chemically treated, and the multinucleate cells obtained were scored at interphase and mitosis. When meristematic cells are treated with γ-hexachlorocyclohexane in appropriate culture conditions, the anaphase chromatids are distributed into discrete unbalanced groups. This phenomenon has been profited for inducing viable multinucleate cells with aneuploid nuclei after cytokinesis inhibition with caffeine.     

The effect of 835.62 MHz FDMA or 847.74 MHz CDMA modulated radiofrequency radiation on the induction of micronuclei in C3H 10T(1/2) cells

To determine if radiofrequency (RF) radiation induces the formation of micronuclei, C3H 10T(1/2) cells were exposed to 835.62 MHz frequency division multiple access (FDMA) or 847.74 MHz code division multiple access (CDMA) modulated RF radiation. After the exposure to RF radiation, the micronucleus assay was performed by the cytokinesis block method using cytochalasin B treatment. The micronuclei appearing after mitosis were scored in binucleated cells using acridine orange staining. The frequency of micronuclei was scored both as the percentage of binucleated cells with micronuclei and as the number of micronuclei per 100 binucleated cells. Treatment of cells with cytochalasin B at a concentration of 2 microg/ml for 22 h was found to yield the maximum number of binucleated cells in C3H 10T(1/2) cells. The method used for the micronucleus assay in the present study detected a highly significant dose response for both indices of micronucleus production in the dose range of 0.1-1.2 Gy and it was sensitive enough to detect a significant (P > 0.05) increase in micronuclei after doses of 0.3 Gy in exponentially growing cells and after 0.9 Gy in plateau-phase cells. Exponentially growing cells or plateau-phase cells were exposed to CDMA (3.2 or 4.8 W/kg) or FDMA (3.2 or 5.1 W/kg) RF radiation for 3, 8, 16 or 24 h. In three repeat experiments, no exposure condition was found by analysis of variance to result in a significant increase relative to sham-exposed cells either in the percentage of binucleated cells with micronuclei or in the number of micronuclei per 100 binucleated cells. In this study, data from cells exposed to different RF signals at two SARs were compared to a common sham-exposed sample. We used the Dunnett's test, which is specifically designed for this purpose, and found no significant exposure-related differences for either plateau-phase cells or exponentially growing cells. Thus the results of this study are not consistent with the possibility that these RF radiations induce micronuclei.     

Comparative quantitative structure toxicity relationships for flavonoids evaluated in isolated rat hepatocytes and HeLa tumor cells

Quantitative structure activity relationship (QSAR) equations were obtained to describe the cytotoxicity of 22 polyphenols using toxicity (logLD50) representing the concentration for 50% cell survival in 2 h for isolated rat hepatocytes, log P representing octanol/water partitioning, and/or E(p/2) representing redox potential. One- and two-parameter equations were derived for the quantitative structure toxicity relationships (QSTR) for polyphenol induced hepatocyte cytotoxicity: e.g. log C(hepatocyte) (microM)=-0.65(-0.08)log P+4.12(-0.15) (n=19, r(2)=0.80, s=0.33, P<1 x 10(-6)). One- and two-parameter QSAR equations were also derived to describe the inhibitory effects of 13 polyphenols on tumor cell growth when incubated with HeLa cells for 3 days: e.g. log C(tumor) (microM)=-0.34(+/-0.04)log P+2.40(+/-0.07) (n=11, r(2)=0.90, s=0.13, P<1 x 10(-5)). These findings point to lipophilicity as a major characteristic determining polyphenol cytotoxicity. The E(p/2) also played a significant role in polyphenol cytotoxicity towards both cell types: e.g. log C(hepatocyte) (microM)=-0.60(+/-0.06)log P+2.01(+/-0.43)E(p/2) (V)+3.86(+/-0.12) (n=9, r(2)=0.96, s=0.15, P<0.005). The involvement of log P and E(p/2) could be explained if polyphenol cytotoxicity involved the formation of radicals, which interacted with the mitochondrial inner membrane resulting in a disruption of the membrane potential.     

Computerized video time-lapse analysis of apoptosis of REC:Myc cells X-irradiated in different phases of the cell cycle

Asynchronous rat embryo cells expressing Myc were followed in 50 fields by computerized video time lapse (CVTL) for three to four cycles before irradiation (4 Gy) and then for 6-7 days thereafter. Pedigrees were constructed for single cells that had been irradiated in different parts of the cycle, i.e. at different times after they were born. Over 95% of the cell death occurred by postmitotic apoptosis after the cells and their progeny had divided from one to six times. The duration of the process of apoptosis once it was initiated was independent of the phase in which the cell was irradiated. Cell death was defined as cessation of movement, typically 20-60 min after the cell rounded with membrane blebbing, but membrane rupture did not occur until 5 to 40 h later. The times to apoptosis and the number of divisions after irradiation were less for cells irradiated late in the cycle. Cells irradiated in G(1) phase divided one to six times and survived 40-120 h before undergoing apoptosis compared to only one to two times and 5-40 h for cells irradiated in G(2) phase. The only cells that died without dividing after irradiation were irradiated in mid to late S phase. Essentially the same results were observed for a dose of 9.5 Gy, although the progeny died sooner and after fewer divisions than after 4 Gy. Regardless of the phase in which they were irradiated, the cells underwent apoptosis from 2 to 150 h after their last division. Therefore, the postmitotic apoptosis did not occur in a predictable or programmed manner, although apoptosis was associated with lengthening of both the generation time and the duration of mitosis immediately prior to the death of the daughter cells. After the non-clonogenic cells divided and yielded progeny entering the first generation after irradiation with 4 Gy, 60% of the progeny either had micronuclei or were sisters of cells that had micronuclei, compared to none of the progeny of clonogenic cells having micronuclei in generation 1. However, another 20% of the non-clonogenic cells had progeny with micronuclei appearing first in generation 2 or 3. As a result, 80% of the non-clonogenic cells had progeny with micronuclei. Furthermore, cells with micronuclei were more likely to die during the generation in which the micronuclei were observed than cells not having micronuclei. Also, micronuclei were occasionally observed in the progeny from clonogenic cells in later generations at about the same time that lethal sectoring was observed. Thus cell death was associated with formation of micronuclei. Most importantly, cells irradiated in late S or G(2) phase were more radiosensitive than cells irradiated in G(1) phase for both loss of clonogenic survival and the time of death and number of divisions completed after irradiation. Finally, the cumulative percentage of apoptosis scored in whole populations of asynchronous or synchronous populations, without distinguishing between the progeny of individually irradiated cells, underestimates the true amount of apoptosis that occurs in cells that undergo postmitotic apoptosis after irradiation. Scoring cell death in whole populations of cells gives erroneous results since both clonogenic and non-clonogenic cells are dividing as non-clonogenic cells are undergoing apoptosis over a period of many days.     

Mutagenic effects of dimethyl terephthalate on mouse somatic cells in vivo

The mutagenic activity of dimethyl terephthalate (DMtP) was evaluated in the micronucleus test in mice. A clear clastogenic effect was obtained at all concentrations studied (0.2-1.0 mmole/kg body weight). The maximum number of micronuclei occurred 24 h after a single intraperitoneal (i.p.) injection. The time-course for the DMtP-induced micronuclei was in agreement with the available data on the rapid excretion of phthalates from the mammalian body. The dose-effect response was best described by a linear equation with a logarithmic component. The emergence of the latter term was related to the toxic effects of DMtP at higher concentrations on bone marrow erythropoietic function. A comparison of the effects induced by DMtP and by methyl nitrosourea indicated that DMtP cannot be considered a strong mutagenic compound. We have compared the sensitivity of the mouse micronucleus test and that of Drosophila dominant-lethal test by contrasting the effects obtained at similar exposure doses. This comparison leads to the conclusion that the micronucleus test is capable of responding to far lower phthalate concentrations than the Drosophila dominant-lethal mutation test. Our results testify to the ability of dimethyl terephthalate to cause genotoxic damages in vivo in both somatic and germinal cells of higher organisms. Thus, the chemical in question may be of potential genetic hazard to man.     

Possible relationship between micronucleated and binucleated cells induced by cisplatin in cultured CHO cells

Chinese hamster ovary (CHO) cells were treated with a single dose (10 μg/ml) of cis-diammino-dichloroplatinum (II) (cisplatin) for 1 h and the effect of the drug on the kinetics of proliferation of the cultures was studied. It was found that the drug produces a delay in the proliferation rates of the treated cultures.The induction of micronuclei and binucleated cells (BC) at different times after treatment have also been studied, and the ability of these cells to undergo DNA synthesis (measured as the ability to incorporate [³H]thymidine) is shown.It was found that cisplatin induced a particular type of BC that contains one or more micronuclei rather than a pure population of BC. The results obtained show a possible relationship between micronuclei and BC. The possibility that some of the micronucleated cells evolve in subsequent cell divisions to BC with micronuclei is suggested.     

Effect of various concentrations of acyclovir on cell survival and micronuclei induction on cultured HeLa cells

The HeLa cells were treated with 0, 0.01, 0.1, 1, 10 and 100 microM acyclovir (ACV) for 8 h duration and the growth kinetics, cell survival and micronuclei induction were determined. Treatment of HeLa cells with various concentrations of ACV resulted in a concentration-dependent decline in growth kinetics, cell proliferation indices and cell survival. ACV, 100 microM, completely inhibited cell division, where no appreciable changes in cell number were observed from 1 to 5 days post-treatment. This is reflected in cell survival, where the surviving fraction of cells was reduced to 1/2 at 100 microM ACV. Conversely, the frequency of micronuclei showed a concentration-dependent elevation at 20, 30 and 40 h post-treatment. ACV not only induced one micronuclei-bearing binucleate cell but also binucleate cells bearing two and multiple micronuclei in a concentration-dependent manner. The micronuclei frequency increased with time up to 30 h post-treatment and declined thereafter. The relationship between micronuclei induction and cell survival was determined by plotting the former on Y- and the latter on X-axes, respectively. The surviving fraction of cells declined with the elevation in micronuclei frequency and a best fit was observed for linear quadratic formalism.     

Micronuclei in lymphocytes with preserved cytoplasm: A method for assessment of cytogenetic damage in man

The micronucleus method for studying cytogenetic effects in lymphocytes in man was modified. The cells were analyzed with preserved cytoplasm, which allowed a more precise identification of micronuclei. The method was tested on 58 individuals 38 of whom were exposed to styrene. Higher frequencies of micronuclei were obtained in 96-h cultures than in 72-h ones. In cells X-rayed in vitro a culture time of 80–88 h gave a maximal frequency of micronuclei. There was a very close correlation between the results of cultures from whole blood and from ‘buffy coat’ (r = 0.99). There was also a good correlation between two observers (r = 0.95), but a systematic difference of about 30% existed between the two sets of observations. The method error (variation coefficient) was 11 and 6% in preparations with mean micronuclei frequencies of 4 and 38%, respectively. The styrene-exposed group displayed weak but statistically significant correlations between frequencies of micronuclei and numerical chromosome aberrations. There were statistically significant effects of age, smoking and low levels of styrene exposure but these factors explained only 12–24% of the total variance.     

Diesel exhaust particulate matter induces multinucleate cells and zinc transporter-dependent apoptosis in human airway cells

The cellular effects of biodiesel emissions particulate matter (BDEP) and petroleum diesel emissions particulate matter (PDEP) were compared using a human airway cell line, A549. At concentrations of 25 microg/ml, diesel particulate matter induced the formation of multinucleate cells. In cells treated with a mixture of 80% PDEP:20% BDEP, 52% of cells were multinucleate cells compared with only 16% of cells treated with 20% PDEP:80% BDEP with a background multinucleate rate of 7%. These results demonstrate a causal relation between the formation of multinucleate cells and exposure to exhaust particulate matter, in particular diesel exhaust. Exposure of A549 cells to PDEP induced apoptosis, seen by active caspase-3 expression and the presence of cleaved pancytokeratin. PDEP exhaust was a much stronger inducer of cellular death through apoptosis than BDEP. There was an eightfold increase in the expression of SLC30A3 (zinc transporter-3 or ZnT3) in cells exposed to 80% PDEP:20% BDEP compared to untreated cells. The increase in ZnT3 expression seen in apoptotic cells following PDEP suggests a role for this zinc transporter in the apoptotic pathway, possibly through controlling zinc fluxes. As exposure to diesel exhaust particles is associated with asthma and apoptosis in airway cells, diesel exhaust particles may directly contribute to asthma by inducing epithelial cell death through apoptotic pathway.     

Biological responses in known bystander cells relative to known microbeam-irradiated cells

Normal human fibroblasts in plateau phase ( congruent with 95% G(1) phase) were stained with the vital nuclear dye Hoechst 33342 (blue fluorescence) or the vital cytoplasmic dye Cell Tracker Orange (orange fluorescence) and plated at a ratio of 1:1. Only the blue-fluorescing nuclei were microbeam-irradiated with a defined number of 90 keV/microm alpha particles. The orange-fluorescing cells were then "bystanders", i.e. not themselves hit but adjacent to cells that were. Hit cells showed a fluence-dependent induction of micronuclei as well as delays in progression from G(1) to S phase. Known bystander cells also showed enhanced frequencies of micronuclei (intermediate between those seen in irradiated and control cells) and transient cell cycle delays. However, the induction of micronuclei in bystander cells did not appear to be dependent on the fluence of the particles delivered to the neighboring hit cells. These are the first studies in which the bystander effect has been visualized directly rather than inferred. They indicate that the phenomenon has a quantitative basis and imply that the target for radiation effects cannot be considered to be the individual cell.     

Embryos and culture cells: a model for studying the effect of progesterone

A positive association between P4 concentration and initial bovine embryo survival has been reported. The objective of this study was to establish two coculture systems as a model to study the influence of progesterone on the initial bovine embryo development. Granulosa cells (GC) or bovine oviduct epithelial cells (BOECs) were used at the base of embryo culture medium microdroplets (TCM199 and 10% of superovulated oestrus cow serum, (SOCS)) supplemented or not with progesterone (P4, 33.4 ng mL(-1)) and/or a progesterone receptor antagonist (onapristone, OP, 2.2x10(-5)M). Presumptive zygotes were transferred to monolayers after in vitro maturation and fertilization of bovine oocytes with thawed swim-up selected sperm. Embryo development was carried out according to the following groups: experiment 1, BOEC (n=378) and BOEC plus OP (n=325); experiment 2, GC (n=514); GC plus OP (n=509); BOEC (n=490); BOEC plus P4 (n=500); BOEC plus P4 and OP (n=502). Embryos were checked for cleavage at day 2 and for stage development between days 8 and 12 of culture. In experiment 1, no differences (P>0.05) were identified between BOEC and BOECOP groups for embryo rates of development, quality or developmental stages. Also in experiment 2, no differences were found in embryo rates of development, quality or developmental stages between embryos cultured under the two coculture systems when no supplementation was added. Embryo development rates were not affected by OP presence in GCOP group. However, P4 negatively affected Day 8 (D8) embryo development rates in BOEC system (BOECP4=16.8+/-2.6% vs. BOEC=23.7+/-1.7%, P=0.02). This negative effect was abolished when P4 antagonist (OP) was added to the culture medium. BOEC supplementation with P4 also induced a delay on embryo development at D8 as confirmed by a lower development score (BOECP4=3.0+/-1.4 vs. GC=3.4+/-0.1, GCOP=3.5+/-0.1, BOEC=3.4+/-0.1 and BOECP4OP=3.5+/-0.1; P<0.05). These results demonstrate that OP supplementation had no harmful effect on embryo development either in granulosa, where P4 is naturally synthesised, or in BOEC coculture systems. Also we can not confirm a direct association between high P4 concentrations and embryo survival during early stages, although P4 may influence early embryo development through different mechanisms mediated by the type of cells present.