Directed positioning of nuclei in living Paramecium tetraurelia: Use of the laser optical force trap for developmental biology

We have constructed a laser optical force trap (“laser tweezers”) by coupling an Nd:YAG laser to an optical microscope with a high numerical aperture objective. The laser beam (approximately 0.1 W power) is focused to a diffraction-limited spot at the specimen plane of the objective: the wavelength chosen (1,064 nm) is not strongly absorbed by most biological materials and is thus not ablative. Because the intensity of the laser beam increases towards the center of the focal spot, small particles brought near the spot will be attracted to the center and held there. Movement of the laser beam will tend to move any trapped particles with it. The laser tweezers can permit precise, nondestructive repositioning of small structures inside a living cell, without recourse to micromanipulators. Initial work has involved the use of laser tweezers on cells of Paramecium tet-raurelia held by a rotocompressor. We have been able to trap and reposition small organelles, especially the highly refractile structures known as crystals. Using a trapped crystal as a “tool”, we have been able to push micronuclei and other structures for many micrometers to virtually any desired location in a cell. In spite of extended exposure of specific structures and of individual cells to the laser beam, no damage has been detectible. Exposed cells, which were removed from the rotocompres-sor and cultured, showed complete viabilty. The laser tweezers technique shows tremendous potential for applications to the study of many fundamental cellular and developmental phenomena in paramecia and other ciliates. For example, we intend to use this technique to investigate temporal and spatial characteristics of nuclear determining regions during sexual reorganization in Paramecium. © 1992 Wiley-Liss, Inc.     

The fate of micronucleated cells post X-irradiation detected by live cell imaging

Micronuclei are closely related to DNA damage. The presence of micronuclei in mammalian cells is a common phenomenon post ionizing radiation. The level of micronucleation in tumor cells has been used to predict prognosis after radiotherapy in many cancers. In order to understand how irradiation-induced micronuclei affect cell fate, we performed extensive long-term live cell imaging on X-irradiated nasopharyngeal carcinoma (NPC) cells. To visualize the dynamics of micronuclei more clearly, chromosomes were stably labeled with red fluorescent protein (RFP) by targeting to human histone H2B. Initially, significantly more micronuclei were observed in radiosensitive cells than in radioresistant cells post irradiation. Additionally, cells with micronuclei were found to be more likely to die or undergo cell cycle arrest when compared with micronucleus-free cells after irradiation, and the more micronuclei the cells contained the more likely they would die or undergo arrest. Moreover, micronucleated cells showed predisposition to produce daughter cells with micronuclei through chromosome lagging. Fluorescence in situ hybridization using human pan-centromeric probes revealed that about 70% of these micronuclei and lagging chromosomes did not contain centromeric signals. Finally, DNA damage was more severe and p38 stress kinase activity was higher in micronucleated cells than in micronucleus-free cells as shown by phospho-H2AX and phospho-p38 immunofluorescence staining. Altogether, our observations indicated that the presence of micronuclei coupled with activated DNA damage response could compromise the proliferation capacity of irradiated cells, providing the evidence and justification for using micronucleus index as a valuable biomarker of radiosensitivity.     

Induction of kinetochore positive and negative micronuclei in V79 cells by N-methyl-N′-nitro-N-nitrosoguanidine: the protective effect of the pyridoindole antioxidant stobadine

The induction of micronuclei by N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) and their reduction by the cardioprotective synthetic antioxidant, stobadine were studied in hamster V79 cells cultured in vitro. The micronuclei derived from acentric fragments or from whole chromosomes were evaluated with the help of an immunofluorescent staining using antikinetochore antibodies from the serum of scleroderma (CREST syndrome) patients. Our results showed that MNNG (0.5 μg/ml) induced mainly kinetochore-negative micronuclei. At 6, 24 and 48 h after MNNG treatment, we measured a 2.7-, 4.3- and 7.0-fold increase, respectively, of kinetochore-negative micronuclei over the controls. The increase of kinetochore-positive micronuclei was rather low and represented at 6, 24 and 48 h, respectively 0.9-, 1.8- and 2.6-fold increases over the controls. Stobadine decreased the level of kinetochore-negative micronuclei at 6, 24 and 48 h to approximately one-half; the frequency of kinetochore-positive micronuclei was reduced only at 6 h. We suppose that the antioxidant stobadine reduces the induction of micronuclei by MNNG by scavenging of MNNG-induced highly reactive OH radicals which cause chromosomal damage.     

Elimination of the germ nuclei of Paramecium tetraurelia by laser microbeam irradiation

The germ nuclei (micronuclei) of Paramecium tetraurelia can be eliminated successfully by irradiating the micronucleus with an argon-ion laser microbeam after sensitization with the dye acridine orange. No immediate cytological damage of the irradiated micronuclei is visible, but they are lost before they enter the next division. This method produces cell lines lacking micronuclei (i.e., amicronucleates). These amicronucleates provide favorable materials for the study of micronuclear functions as well as intra-and inter-specific nucleocytoplasmic interactions. Some preliminary observations show that the micronucleus is not required for macronuclear fragmentation and macronuclear regeneration during sexual reproduction, but suggest that the micronucleus might participate in some asexual cellular function in addition to their gametic role.     

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 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.     

Versatile laser‐based cell manipulator

Here we describe a two‐photon microscope and laser ablation setup combined with optical tweezers. We tested the setup on the fission yeast Schizosaccharomyces pombe, a commonly used model organism. We show that long‐term imaging can be achieved without significant photo‐bleaching or damage of the sample. The setup can precisely ablate sub‐micrometer structures, such as microtubules and mitotic spindles, inside living cells, which remain viable after the manipulation. Longer exposure times lead to ablation, while shorter exposures lead to photo‐bleaching of the target structure. We used optical tweezers to trap intracellular particles and to displace the cell nucleus. Two‐photon fluorescence imaging of the manipulated cell can be performed simultaneously with trapping. The combination of techniques described here may help to solve a variety of problems in cell biology, such as positioning of organelles and the forces exerted by the cytoskeleton. (© 2008 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Cytotoxicity of azadirachtin A in human glioblastoma cell lines

The neem toxin azadirachtin A exhibits selective toxicity on insects. Despite its well-proven efficacy, the mode of action of this toxin remains obscure. The toxicity on vertebrate cells compared to insect cells is also not well characterized. We have cultivated six human glioblastoma cell lines G-28, G-112, G-60 (TP53 mutant) and G-44, G-62, G-120 (TP53 wild-type) in the presence of 28 microM of azadirachtin. This toxin concentration was chosen because it represents the 25 to 50% lethal dose in the glioma cells. Toxicity was measured in terms of cell proliferation (binucleation index), formation of micronuclei and cell survival. In the TP53 mutant cell lines, azadirachtin reduced the proportion of dividing cells and induced formation of micronuclei. Except for G-44 which showed a decrease in binucleation index, proliferation in the TP53 wild-type cell lines was unaffected by azadirachtin. In the TP53 wild-type cell lines, the decrease in micronuclei frequency is attributed to fewer cells entering mitosis to produce micronuclei. This is also apparent from the low surviving fractions. Cell survival was suppressed by 25-69% in all cell lines. The reduction of cell survival is a clear indication that azadirachtin affects reproductive integrity and cell division. The induction of micronuclei reflects DNA damage. Similar studies on damage induction in insect cell lines could elucidate the processes which precede the antifeedant and antimoulting effects of azadirachtin and other neem toxins in insects.     

No evidence for genotoxic effects from 24 h exposure of human leukocytes to 1.9 GHz radiofrequency fields

The current study extends our previous investigations of 2-h radiofrequency (RF)-field exposures on genotoxicity in human blood cell cultures by examining the effect of 24-h continuous-wave (CW) and pulsed-wave (PW) 1.9 GHz RF-field exposures on both primary DNA damage and micronucleus induction in human leukocyte cultures. Mean specific absorption rates (SARs) ranged from 0 to 10 W/kg, and the temperature within the cultures was maintained at 37.0 +/- 1.0 degrees C for the duration of the 24-h exposure period. No significant differences in primary DNA damage were observed between the sham-treated controls and any of the CW or PW 1.9 GHz RF-field-exposed cultures when processed immediately after the exposure period by the alkaline comet assay. Similarly, no significant differences were observed in the incidence of micronuclei, incidence of micronucleated binucleated cells, frequency of binucleated cells, or proliferation index between the sham-treated controls and any of the CW or PW 1.9 GHz RF-field-exposed cultures. In conclusion, the current study found no evidence of 1.9 GHz RF-field-induced genotoxicity in human blood cell cultures after a 24-h exposure period.     

Development of a dual joystick‐controlled laser trapping and cutting system for optical micromanipulation of chromosomes inside living cells

A multi‐joystick robotic laser microscope system used to control two optical traps (tweezers) and one laser scissors has been developed for subcellular organelle manipulation. The use of joysticks has provided a “user‐friendly” method for both trapping and cutting of organelles such as chromosomes in live cells. This innovative design has enabled the clean severing of chromosome arms using the laser scissors as well as the ability to easily hold and pull the severed arm using the laser tweezers. (© 2013 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Antioxidant vitamins C, E and beta-carotene reduce DNA damage before as well as after gamma-ray irradiation of human lymphocytes in vitro

The protective effect of Vitamins C, E and beta-carotene against gamma-ray-induced DNA damage in human lymphocytes in vitro was investigated. Cultured lymphocytes were exposed to increasing concentration of these vitamins either before or after irradiation with 2Gy of gamma-rays and DNA damage was estimated using micronucleus assay. A radioprotective effect was observed when antioxidant vitamins were added to cultured cells before as well after irradiation; the strongest effect was observed when they were added no later than 1h after irradiation. The radioprotective effect of vitamins also depended on their concentration; Vitamins C added at low concentration (1 microg/ml) before exposure of the cells to radiation prevented induction of micronuclei. Vitamin E at the concentration above 2 microg/ml decreased the level of radiation-induced micronuclei when compared to the cells irradiated without vitamin treatment. beta-Carotene was effective at all tested concentrations from 1 to 5 microg/ml and reduced the number of micronuclei in irradiated cells. The vitamins had no effect on radiation-induced cytotoxicity as measured by nuclear division index. The radioprotective action of antioxidant Vitamins C, E and beta-carotene was dependent upon their concentration as well as time and sequence of application.     

Lack of Mitotic Delays at the Onset of Proliferation in Dormant Root Primordia Challenged by Ionizing Radiation

X-rays at doses between 2.5 and 20 Gy were applied to Allium cepa L. bulbs containing either dormant root primordia (before water imbibition) or actively proliferating meristems. Irradiation of the primordia that were enriched in G₀ cells neither delayed proliferation onset nor root sprouting. Under both protocols, irradiation decreased the final length of the roots to about 60 % (at 20 Gy) of that reached by the unirradiated controls. Irradiation of the proliferating meristems increased the mitotic index at some fixation times. This could not be due to a rise in the cell entry into mitosis, as the rate of root growth decreased simultaneously. The increased mitotic index should be the consequence of a delay in the relative time taken by mitosis in the whole cycle time. Lengthened mitosis probably allows the post-replicative repair of most DNA lesions, as the frequency of interphases with micronuclei was higher in the cells which were irradiated when still dormant than in those irradiated when cycling. Thus, the mitotic delays should be the consequence of a checkpoint pathway activated by the presence of DNA damage. This feedback mechanism seems only to develop after cell proliferation is restored. This revised version was published online in July 2006 with corrections to the Cover Date.     

Effects of diethylstilboestrol-dipropionate on SCEs, micronuclei, cytotoxicity, aneuploidy and cell proliferation in maternal and foetal mouse cells treated in vivo

The effect of diethylstilboestrol-dipropionate on the frequency of SCEs and micronuclei, cytotoxicity, aneuploidy and cell proliferation rates of foetal liver and maternal bone marrow cells following exposure of pregnant mice was measured. An increase in the number of aneuploid and polyploid cells was observed in both tissues. There was no effect on micronuclei frequency, SCE frequency, or cell proliferation rate.     

Holospora elegans-Infected Micronuclei of Paramecium caudatum Still Serve a Function During Vegetative Life1

The fission rate of Paramecium caudatum cells infected with the micronucleus-specific bacterium Holospora elegans was examined before and after elimination of the micronucleus. Uninfected cells, micronucleate and amicronucleate, were used as controls. Emicronucleation of Holospora elegans-infected cells causes a decrease of fission rates, as is observed after emicronucleation of uninfected cells. This is taken as an argument that infected micronuclei still serve a function for the vegetative life of P. caudatum.     

Vicia faba chromosome damage induced by low doses of gamma radiation

The rate of radiation damage to chromosomes by low doses of gamma rays (0.01-0.30 Gy) was studied in the root tips ofVicia faba. As criteria of the effect of ionizing radiation, the frequency of sister chromatid exchanges (SCEs), incidence of chromosomal aberrations and the number of micronuclei were evaluated and compared in irradiated cells. The results obtained confirmed that the analysis of SCEs did not represent an efficient indicator of radiation damage to chromosomes. On the contrary, the formation of chromosomal aberrations and micronuclei was effectively stimulated by low radiation doses, there being linear dose-effect relationships in the low doses region used.     

Analysis of germinal aging in Paramecium caudatum by micronuclear transplantation

The role of the micronucleus in the age-dependent increase in mortality after conjugation in Paramecium has been investigated using micronuclear transplantation. The clone of Paramecium caudatum used for this study had a lifespan of about 750 fissions. In this clone, the fission rate began to decrease about 450 fissions after conjugation. Mortality after selfing conjugation also began to appear at about 450 fissions and gradually increased with clonal age. Cells at about 650 fissions showed 10–70% survival after selfing conjugation but when their micronuclei were transplanted into amicronucleate cells of about 450 fissions, the progeny survival increased to 70–90%. When micronuclei from cells 700–750 fissions old were transplanted into amicronucleate cells of 100–150 fissions, however, increase in progeny survival was very rare. The results indicate that micronuclei in cells up to the age of 650 fissions can function normally if the cytoplasmic environment is young.     

FISH in analysis of gamma ray-induced micronuclei formation in barley

A micronucleus test in combination with fluorescent in situ hybridization (FISH) using telomere-, centromere-specific probes and 5S and 25S rDNA was used for a detailed analysis of the effects of gamma ray irradiation on the root tip meristem cells of barley, Hordeum vulgare (2n = 14). FISH with four DNA probes was used to examine the involvement of specific chromosomes or chromosome fragments in gamma ray-induced micronuclei formation and then to explain their origin. Additionally, a comparison of the possible origin of the micronuclei induced by physical and chemical treatment: maleic hydrazide (MH) and N-nitroso-N-methylurea (MNU) was done. The micronuclei induced by gamma ray could originate from acentric fragments after chromosome breakage or from whole lagging chromosomes as a result of a dysfunction of the mitotic apparatus. No micronuclei containing only centromeric signals were found. An application of rDNA as probes allowed it to be stated that 5S rDNA–bearing chromosomes are involved in micronuclei formation more often than NOR chromosomes. This work allowed the origin of physically- and chemically-induced micronuclei in barley cells to be compared: the origin of micronuclei was most often from terminal fragments. FISH confirmed its usefulness in the characterization of micronuclei content, as well as in understanding and comparing the mechanisms of the actions of mutagens applied in plant genotoxicity.     

Persistence of genetic damage in lymphocytes from former uranium miners

Lymphocytes from former uranium miners who finished work underground one or more decades ago were analysed with respect to possibly persisting genetic damage induced by their radiation exposure. A modified micronucleus-centromere test was used which determined the frequency of micronucleus-containing binucleate cells after cytochalasin B treatment and the percentage of centromere-free micronuclei, assessed with the help of immunofluorescence labeling of centromere protein B. Whereas the overall frequency of micronucleus-containing cells was not significantly elevated above the level found in a control group, former miners showed a greater percentage of centromere-free micronuclei, i.e. micronuclei containing only acentric fragments. Our results are in excellent agreement with those of an earlier uranium miner study and lend support to the assumption that genetic damage from alpha radiation can persist for many years after exposure, possibly due to genomic instability. The frequency of micronucleus-containing cells, but not the percentage of centromere-free micronuclei, significantly increased with time since last exposure in the mines. This can be attributed, at least in part, to the fact that miners who have finished working underground longer ago tend to be older, and there is an increase of the frequency of micronucleus-containing cells with age.     

Cancer cells that survive checkpoint adaptation contain micronuclei that harbor damaged DNA

We have examined the relationship between checkpoint adaptation (mitosis with damaged DNA) and micronuclei. Micronuclei in cancer cells are linked to genomic change, and may induce chromothripsis (chromosome shattering). We measured the cytotoxicity of the cancer drug cisplatin in M059K (glioma fibroblasts, IC50 15 μM). Nearly 100% of M059K cells were positive for histone γH2AX staining after 48 h treatment with a cytotoxic concentration of cisplatin. The proportion of micronucleated cells, as confirmed by microscopy using DAPI and lamin A/C staining, increased from 24% to 48%, and the total micronuclei in surviving cells accumulated over time. Promoting entry into mitosis with a checkpoint inhibitor increased the number of micronuclei in cells whereas blocking checkpoint adaptation with a Cdk inhibitor reduced the number of micronuclei. Interestingly, some micronuclei underwent asynchronous DNA replication, relative to the main nuclei, as measured by deoxy-bromo-uracil (BrdU) staining. These micronuclei stained positive for histone γH2AX, which was linked to DNA replication, suggesting that micronuclei arise from checkpoint adaptation and that micronuclei may continue to damage DNA. By contrast the normal cell line WI-38 did not undergo checkpoint adaptation when treated with cisplatin and did not show changes in micronuclei number. These data reveal that the production of micronuclei by checkpoint adaptation is part of a process that contributes to genomic change.     

Bystander effects induced by direct and scattered radiation generated during penetration of medium inside a water phantom

Background

The biological effects of ionizing radiation have long been thought to results from direct targeting of the nucleus leading to DNA damage. Over the years, a number of non-targeted or epigenetic effects of radiation exposure have been reported where genetic damage occurs in cells that are not directly irradiated but respond to signals transmitted from irradiated cells, a phenomenon termed the “bystander effects”.

Aim

We compared the direct and bystander responses of human A 549, BEAS-2-B and NHDF cell lines exposed to both photon (6 MV) and electron (22 MeV) radiation inside a water phantom. The cultures were directly irradiated or exposed to scattered radiation 4 cm outside the field. In parallel, non-irradiated cells (termed bystander cells) were incubated in ICM (irradiation conditioned medium) collected from another pool of irradiated cells (termed donor cells).

Materials and methods

In directly irradiated cells as well as ICM-treated cells, the frequency of micronuclei and condensation of chromatin characteristic for the apoptotic process were estimated using the cytokinesis-block micronucleus test.

Results

In all tested cell lines, radiation induced apoptosis and formation of micronuclei. A549 and BEAS-2B cells cultured in ICM showed increased levels of micronuclei and apoptosis, whereas normal human fibroblasts (NHDF line) were resistant to bystander response. In A549 and BEAS-2B cells placed outside the radiation field and exposed to scattered radiation the formation of micronuclei and induction of apoptosis were similar to that after ICM-treatment.

Conclusion

Results suggest that the genetic damage in cells exposed to scattered radiation is caused by factors released by irradiated cells into the medium rather than by DNA damage induced directly by X rays. It seems that bystander effects may have important clinical implications for health risk after low level radiation exposure of cells lying outside the radiation field during clinical treatment.