Blue Light Inhibits Mitosis in Tissue Culture Cells

Irradiation of the mitotic (prophase and prometaphase) tissue culture PK (pig kidney embryo) cells using mercury arc lamp and band-pass filters postponed or inhibited anaphase onset. The biological responses observed after irradiation were: (i) normal cell division, (ii) delay in metaphase and then normal anaphase and incomplete cytokinesis, (iii) exit into interphase without separation of chromosomes, (iv) complete mitotic blockage. Cell sensitivity to the light at wavelengths from 423 and 488 nm was nearly the same; to the near UV light (wavelength 360 nm) it was 5–10 times more; to the green light (wavelength >500 nm) it was at least 10 times less. To elucidate the possible mechanism of the action of blue light we measured cell adsorption and examined cell autofluorescence. Autofluorescence of cytoplasmic granules was exited at wavelengths of 450–490 nm, but not at >500 nm. In mitotic cells fluorescent granules accumulated around the spindle. We suppose blue light irradiation induces formation of the free radicals and/or peroxide, and thus perturb the checkpoint system responsible for anaphase onset.     

Optical trapping for chromosome manipulation: a wavelength dependence of induced chromosome bridges.

Using a tunable titanium-sapphire laser, we have compared different wavelengths (from 700 to 840 nm) for their utility in optical trapping of chromosomes in mitotic rat kangaroo Potorous tridactylus (PtK2) cells. It was found that irradiation with a near-infrared light induces the sticking together of chromosome shoulders. The attached chromatids failed to separate, or separated with significant delay and formed a chromosome bridge during anaphase. Using this bridge (and induced c-mitosis) as a reference, we compared the action of different wavelengths (from 700 to 840 nm). Chromosomes were irradiated at metaphase and the cells were observed until the end of cytokinesis. Chromosomes were irradiated for different periods of time, using 130 mW of power at the objective focal plane. The biological responses observed after optical trapping were: (1) normal cell division, (2) formation of a temporary chromosome bridge, (3) formation of a permanent chromosome bridge, (4) complete blockage of chromosome separation (c-mitosis). The chromosomes were found to have a maximal sensitivity to 760-765 nm light and minimal sensitivity to 700 and 800-820 nm light. Cells with chromosomes irradiated for a long time, using wavelength 760-765 nm, generally were incapable of going through anaphase and remained in c-mitosis. We conclude that the optimal wavelengths for optical trapping are 700 and 800-820 nm.     

Proliferation and tumorigenity of murine hepatoma cells irradiated with polychromatic visible and infrared light

In experiments in vitro, the effects of polychromatic visible (VIS) light combined with polychromatic infrared light (VIS-IR, 480–3400 nm) and the effects of the entire spectrum of VIS radiation (385–750 nm) on viability and proliferative activity of the murine hepatoma cells MH22a were studied. In experiments in vivo, changes in the tumorigenic properties of cells MH22a were studied after the same kinds of light exposure. It was shown that irradiation of hepatoma cells with two kinds of polychromatic light at a wide range of doses (4.8–38.4 J/cm²) did not lead to an increase in the number of dead cells for 24–72 h of cultivation and did not cause deceleration of the hepatoma cell proliferation; moreover, the VIS-IR light at a dose of 4.8 J/cm² and the VIS light at a dose 38.4 J/cm² even promoted more intense cell proliferation after 24 h. In cells irradiated with VIS-IR and VIS light, the proliferation index rose by 1.6 and 1.4 times, respectively, and the time of the cells’ number doubling decreased as compared with control. Studying the tumorigenic properties of irradiated tumor cells has shown that, for 30 days after transplantation to syngenic mice C3HA of hepatoma cells 24 h after their irradiation with VIS-IR light at a dose of 4.8 J/cm², the tumor volume decreased significantly (2.6–4.1 times) at all periods of observation, while the incidence of tumor formation decreased, whereas the survival of the tumor-bearing mice did not change. Transplantation of cells irradiated with the same light at a dose of 9.6 J/cm² did not lead to significant changes in the tumor volume, the tumor formation incidence, and animal survival. The main contribution to the antitumor effect of VIS-IR light seems to be made by the VIS component, as transplantation into mice of cells irradiated with VIS light alone at a dose of 38.4 J/cm² also stimulating proliferation of hepatoma cells in vitro resulted in a decrease of their tumorigenic properties. However, the IR component in the combined VIS-IR radiation enhanced the antitumor effect of the VIS light; as a result, it was manifested after use of doses eight times lower (4.8 J/cm²) than in the case of VIS light alone (38.4 J/cm²). Mechanisms of the decrease of tumorigenic properties of hepatoma cells after irradiation with polychromatic light at doses stimulating their proliferation in vitro are studied.     

THE EFFECT OF A MEDIUM DOSE (430 ROENTGENS) OF X-RAY IRRADIATION ON RESTING CELLS OF THE LIVER

The mitotic activity of regenerating liver cells after a single dose (430 r) of x-ray irradiation was studied. In every group of the experimental animals (white rats), the mitotic activity (mitotic index) and the number of abnormal mitotic figures were determined. The results indicated that resting cells irradiated a short time before mitotic activity showed reactions similar to those of cells irradiated during mitotic activity. The disturbances in the irradiated mitotically active cells were only quantitatively different from those in the irradiated resting cells. The disturbances in the irradiated resting cells depended upon the time interval between the irradiation and the beginning of mitotic activity stimulated by partial hepatectomy. It was found that the shorter the time interval, the more pronounced were the disturbances and the more similar they became to those of irradiated mitotically active cells. Conversely, the longer the time interval between the irradiation and the beginning of mitotic activity, the less pronounced were the disturbances and the more similar they became to those of the non-irradiated control cells. A discussion is presented as to whether or not the lesions of resting cells caused by a single medium dose of x-ray irradiation are reversible, and whether such lesions are only brought to light by the process of mitosis or whether the process of mitosis renders it possible for these lesions to develop.     

He—Ne激光照射离体鼠巨噬细胞对线粒体跨膜电势的影响

目的：研究Ｈｅ－Ｎｅ激光照射鼠巨噬细胞对线粒体跨膜电势的影响,及其与激光剂量的关系。方法：用亲脂性阳离子荧光染料Ｒｈｏｄａｍｉｎｅ１２３对鼠巨噬细胞线粒体作荧光标记,以不同的激光剂量照射,采用图像分析系统（ＩＡＳ）和荧光显微镜观察线粒体跨膜电势荧光强度的变化。结果：低功率Ｈｅ－Ｎｅ激光照射５,１０,１５ｍｉｎ,激光剂量分别为０．６４９,１．３８８和２．０８２Ｊ／ｃｍ＾２,巨噬细胞线粒体跨膜电势荧光     

Photoinduced antitumour effect of hypericin can be enhanced by fractionated dosing

The in vivo antitumour activity of the natural photosensitizer hypericin was evaluated. C3H/DiSn mice were inoculated with fibrosarcoma G5:1:13 cells. When the tumour reached a volume of 40-80mm3 the mice were intraperitoneally injected with hypericin, either in a single dose (5mg/kg; 1 or 6h before laser irradiation) or two fractionated doses (2.5 mg/kg; 6 and 1 h before irradiation with laser light; 532 nm, 70mW/cm2, 168 J/cm2). All tumours in control groups treated with hypericin alone as well as those irradiated with laser light alone had similar growth rates and none of these tumours regressed spontaneously. Complete remission of tumour in photodynamic therapy (PDT)-treated groups was similar (14-17% single dose vs. 33% fractionated dose), but the fractionated schedule of hypericin dosing was found to be more efficient than the single dose, measured by survival assay (p < 0.05). Our experimental model showed that fractionated administration of hypericin can produce a better therapeutic response than single administration.     

Photomicronucleus assay of phototoxic and pseudophotoclastogenic chemicals in human keratinocyte NCTC2544 cells

Photochemical genotoxicity was evaluated in human keratinocyte NCTC2544 cells. The cells were pre-treated with photogenotoxic or pseudophotoclastogenic chemicals and irradiated with a solar-simulator for 50min at a total UV dose of 5J/cm(2) or placed in the dark for the same period. After washing, the cells were cultured for 1.5-2 cell cycles with fresh culture medium. At the end of culturing, slide specimens were prepared and examined for micronucleus formation. 8-Methoxypsoralen, a photogenotoxic chemical, strongly induced micronucleated cells with UV irradiation but not under non-irradiation conditions. Therefore, NCTC2544 cells were subjected to further investigation to evaluate the possible photogenotoxicity of other chemicals. 6-Methylcoumarin, 3,3',4',5-tetrachlorosalicylanilide and protoporphyrin IX disodium salt, which are all known phototoxic substances, induced micronucleated cells with irradiation but not in the non-irradiation state. These phototoxic substances were confirmed to be photogenotoxic. Tetrabenzoporphine and 5-aminolevulinic acid, which are used for photodynamic therapy, showed phototoxicity. However, these chemicals did not induce micronucleated cells in the irradiated or non-irradiated state, suggesting a lack of photogenotoxicity. Among 3 pseudophotoclastogenic chemicals having no light absorbance at 290-700nm, neither cycloheximide nor disulfoton induced micronucleated cells with or without irradiation; zinc oxide induced micronucleated cells with irradiation and, to a lesser extent, without irradiation. Based on the results of the photogenotoxicity assays of these 9 chemicals, NCTC2544 cells are considered to be a suitable test system to evaluate the photogenotoxic potential of chemicals.     

Comparative effects of 60Co gamma-rays and neon and helium ions on cycle duration and division probability of EMT 6 cells. A time-lapse cinematography study

Exponentially growing cultures of EMT 6 cells were irradiated in vitro with neon ions, helium ions or 60Co gamma-rays. Time-lapse cinematography allowed the determination, for individual cells, of cycle duration, success of the mitotic division and the age of the cell at the moment of irradiation. Irradiation induced a significant mitotic delay increasing proportionally with the delivered dose. Using mitotic delay as an endpoint, the r.b.e. for neon ions with respect to 60Co gamma-rays was 3.3 +/- 0.2 while for helium ions it was 1.2 +/- 0.1. Mitotic delay was greatest in those cells that had progressed furthest in their cycle at the time of irradiation. No significant mitotic delay was observed in the post-irradiation generation. Division probability was significantly reduced by irradiation both in the irradiated and in the post-irradiated generation. The reduction in division probability obtained with 3 Gy of neon ions was similar to that obtained after irradiation with 6 Gy of helium ions or 60Co gamma-rays.     

510.6nm激光照射对兔血管平滑肌细胞增殖的影响

本文用５１０．６ｎｍ 波长激光以功率密度１、５、１０ ｍ Ｗ／ｃｍ ２ 和能量密度２、４、６Ｊ／ｃｍ ２ 照射体外培养的兔血管平滑肌细胞（ＳＭＣ）,通过３Ｈ－ ＴｄＲ掺入率和细胞生长曲线测定细胞增殖率。结果显示,上述激光照射量均能抑制细胞增殖率,其中以１０ｍ Ｗ／ｃｍ ２ 组的作用最为显著     

578.2 nm激光照射对兔视网膜的损伤效应研究

研究578.2 nm激光照射对兔视网膜的作用特点,以新西兰白兔5只10眼为实验对象,铜蒸汽激光(578.2 nm)通过裂隙灯照射兔视网膜后极部,照射时间为100 s,光斑直径为2 mm,照射剂量分别为60 J/cm2、80 J/cm2、100 J/cm2、120 J/cm2、160 J/cm2、200 J/cm2,每组4个光斑。照后1 h及24 h进行眼底照相及光镜观察。照光后可见,随激光功率密度的增加,兔视网膜的损伤也逐渐加重,并且照后24 h的损伤要重于照后1h。80 J/cm2和60 J/cm2在照后1 h和24 h均未发现明显改变。578.2 nm激光照射白兔后的主要病理学改变位于脉络膜。因此,以578.2 nm激光作为光动力治疗眼底疾病的光源时,照射剂量不宜超过80 J/cm2。     

Mitotic reversion in prophase of PTK1 cells induced by argon laser microirradiation

In this paper, we report the effects of laser microirradiation of prophase nucleoli and mitotic chromosomes in cells of female rat kangaroo kidney epithelial cell line PTK1. When the laser power delivered to sample surface was 90-190 mW, irradiation of one of the two nucleoli in the prophase cell did not inhibit the mitotic progress, but resulted in the loss of the irradiated nucleolus in daughter cells. When the laser power was increased to 360-420 mW, either irradiation of the nucleolus or chromosome in midprophase caused a blockage of mitosis at terminal midprophase. The irradiated cells returned morphologically to early prophase. No mitotic reversion occurred in the case of irradiation of chromosomes at late prophase, prometaphase, metaphase, and anaphase. Irradiation of the cytoplasm in prophase cells caused a 50-70 min mitotic delay at prophase. However, the irradiated cells underwent successive mitotic divisions. The mechanism of laser-induced mitotic prophase reversion is discussed.     

In situ control of cell adhesion using photoresponsive culture surface

A photoresponsive culture surface (PRCS) allowing photocontrol of cell adhesion was prepared with a novel polymer material composed of poly(N-isopropylacrylamide) having spiropyran chromophores as side chains. Cell adhesion of the surface was drastically enhanced by the irradiation with ultraviolet (UV) light (wavelength: 365 nm); after subsequent cooling and washing on ice, many cells remained in the irradiated region, whereas most cells were removed from the nonirradiated region. The cell adhesion of the PRCS, which had been enhanced by previous UV irradiation, was reset by the visible light irradiation (wavelength 400-440 nm) and the annealing at 37 degrees C for 2 h. Also it was confirmed that the regional control of cell adhesion was induced several times by repeating the same series of operations. Further, living cell patterning with the 200 microm line width was produced readily by projecting UV light along a micropattern on the PRCS on which the living cells had been seeded uniformly in advance. By using a fluorescent probe that stains living cells only, it was confirmed that the cells maintained sufficient viability even after UV light irradiation followed by cooling and washing.     

The photo comet assay--a fast screening assay for the determination of photogenotoxicity in vitro

Different classes of chemicals can induce a phototoxic effect by absorbing light energy within the wavelength range of sunlight. The assessment of photo-safety is therefore an obligatory part of the development of new drugs. Ten UV-vis (280-800nm)-absorbing compounds (ketoprofen, promazine, chlorpromazine, dacarbazine, acridine, lomefloxacin, 8-methoxypsoralen, chlorhexidine, titanium dioxide, octylmethoxycinnamate) were tested for their photogenotoxic potential in the alkaline comet assay in the presence and absence of UV-vis. In order to establish an easy and timesaving protocol for a photo comet assay screening test, the application of 96-well plates was essential. The use of mouse lymphoma L5178Y cells, a cell line growing in suspension, allowed the determination of photocytotoxicity with the Alamar Blue assay and of photogenotoxicity with the alkaline comet assay in parallel. L5178Y cells were incubated with the test compounds for 20min and irradiated with simulated sunlight in the wavelength range from 280 to 800nm. The applied UV dose was 600mJ/cm(2) UV-A and 30mJ/cm(2) UV-B. After a post-incubation of 10min, the Alamar Blue assay and the alkaline comet assay were performed. All of the compounds which are known to be photogenotoxic (8-methoxypsoralen, acridine, chlorpromazine, dacarbazine, ketoprofen, lomefloxacin) showed a positive effect under our assay conditions. Furthermore, four UV-vis absorbing chemicals which are known to be not photogenotoxic (promazine, chlorhexidine, titanium dioxide, octylmethoxycinnamate) were analysed. For none of them an increase of the DNA damage following irradiation was observed in this study. In conclusion, all of the chemical compounds tested were classified in agreement with published data. From the data presented it is concluded that the photo comet assay with L5178Y mouse lymphoma cells is a reliable model to assess photochemical genotoxicity in vitro.     

Modulating effect of helium-neon laser radiation on the state of antioxidant and hydroxylation systems of quail liver under X-ray irradiation and chemical intoxication

Red laser light (lambda = 633 nm) in a dose of 9.5 mJ/cm2 defends quail's embryo from X-ray irradiation (8.5 Gr). It is expressed in the 1.9 times decrease of embryo mortality on early term of incubation and 1.6 times increase of hatch in a group of embryos, which were affected by X-rays and laser radiation compared with an embryo, irradiated only by X-rays. Repeated laser irradiation of adult quails (dose 21 J) after CCl4-intoxication led to normalization of hydroxylation and antioxidant systems functions.     

The effect of radiation with polychromatic visible and infrared light on the tumorigenicity of murine hepatoma 22A cells and their sensitivity to lysis by natural killers

The tumorigenicity of murine hepatoma cells (MH-22a) and their sensitivity to lysis by natural killers (NKs) have been studied after exposure to polychromatic visible and infrared light (VIS-IR, 480–3400 nm, 40 mW/cm²), similar to the terrestrial solar spectrum without its minor UV component, with the aim of clarifying the participation of this important environmental and physiotherapeutic factor in regulation of antitumor protective system. MH-22 cells were exposed in vitro to VIS-IR light and their sensitivity to lytic activity of NKs was evaluated. It was found that, after exposure to VIS-IR light at a dose of 4.8 J/cm², the sensitivity of MH-22a cells to lysis by NKs increased by 1.5–2 times, while after exposure at a dose of 9.6 J/cm² it did not change at all the ratios of the NKs-number (effectors) to that of hepatoma cells — targets (1 : 5–1 : 50). An increase of the hepatoma cell sensitivity to NKs was accompanied by structural changes of cell surface: the capability of supramembranous glycoproteins (glycocalyx) to sorb the vital dye alcian blue (AB) was significantly lower than in the case of unexposed cells of the control group. However, no changes in AB sorption was revealed in hepatoma cells exposed to light at a dose of 9.6 J/cm². The tumorigenicity of photoirradiated MH-22a cells has been studied in the experiments in vitro. For 25 days after transplantation of light-exposed hepatoma cells to C3HA syngene mice, the tumor volume proved to be smaller after exposure to light at both doses of 4.8 and 9.6 J/cm² than in the control group (by 4–4.5 times and 2.5–4 times, respectively), which correlated with an increase of sensitivity to lysis by NKs and with a decrease of AB sorption after light exposure only at a dose of 4.8 J/cm². Using the flow-cytometry method, we could show that VIS-IR light at the doses used did not interfere with the distribution of hepatoma cells over the cell-cycle phases and, thus, deceleration of the tumor growth was not associated with a cytostatic effect of the VIS-IR light. To evaluate the effect of polychromatic light on growth of the preformed tumors, a 5-day course of daily light exposure of C3HA tumor-bearing mice was performed on the 10th day after subcutaneous transplantation of 2 × 10⁵ cells of syngene hepatoma, when tumors developed in all (100%) animals. As in the case of transplantation of light-exposed cells, irradiation of tumor-bearing mice at doses 4.8–9.6 J/cm² resulted in a deceleration of tumor growth (by 2.1–2.9 and 2,2 times, respectively) for 4 weeks compared with unirradiated mice.     

弱激光对脂质体介导的血管平滑肌细胞基因转染的影响

本研究采用阳离子脂质体介导外源基因转染体外培养的兔血管平滑肌细胞（ＳＭＣ）,在基因转染过程中给予激光照射,用细胞化学染色方法测定基因转染阳性率。结果显示：用５１０．６ｎｍ激光于基因转染前,以功率密度１ｍｗ／ｃｍ２,能量密度２、４、６Ｊ／ｃｍ２和５ｍＷ／ｃｍ２,４、６Ｊ／ｃｍ２;及１０ｍＷ／ｃｍ２,２Ｊ／ｃｍ２进行照射均能显著提高基因转染率（ｐ＜０．０５）;于基因转染后即刻以功率密度１ｍＷ／ｃｍ２、能量密度２Ｊ／ｃｍ２和５ｍＷ／ｃｍ２、６Ｊ／ｃｍ２照射也能提高基因转染率（ｐ＜０．０５）。而用６２７．８ｎｍ激光照射对基因转染率无显著影响     

Transient inhibition of L929 cell mitosis and locomotion by argon ion laser irradiation

Summary Argon ion laser irradiation of L929 cells transiently inhibits both entry into and passage through mitosis without affecting clonogenic survival. Anaphase mitotic figures virtually disappear from irradiated cell monolayers although prophase + metaphase mitotic figures can still be identified. The total number of mitotic figures does not change significantly and time-lapse video recording shows that cells do not enter mitosis following irradiation. This effect is dependent on light dose within the 900–2700 J/cm² range and persists for 10–48 h depending on the initial light exposure. Inhibition of cell locomotion and subsequent recovery were observed to occur over a similar time course. The possible contribution of these phenomena must be considered whenever biological systems are exposed to argon ion laser irradiation.     

Photodynamic activity of 5,10,15,20-tetrakis(4-methoxyphenyl)porphyrin on the Hep-2 human carcinoma cell line: effect of light dose and wavelength range.

The photodynamic activity of 5,10,15,20-tetrakis(4-methoxyphenyl)porphyrin (TMP) has been investigated in two systems: reverse micelles of n-heptane/sodium bis(2-ethylhexyl)sulfosuccinate (AOT)/water-bearing photooxidizable substrates and on a Hep-2 human carcinoma cell line. The effect of variation in the light dose and wavelength range (360-800, 455-800, and 590-800 nm) was compared in both media. The aerobic singlet oxygen-mediated photooxidation of L-tryptophan (Trp) was used as a model of biological substrate in a micellar system. A considerable increase of the observed rate constants of Trp (k(Trp)(obs)) was noted, increasing the irradiated area of the TMP spectrum. In vitro, the survival curves of Hep-2 cells, treated with TMP, were markedly dependent on the light wavelength ranges used for irradiation. A linear behavior between k(Trp)(obs) and the photoinactivation rate of Hep-2 cells was found, indicating that the singlet oxygen (1O2 ) is the main species responsible for cell inactivation. These results contributed to an understanding of the photodynamic process yielded by this porphyrin in vitro and the sensitivity of Hep-2 cells to photodamage.     

Effects of UV-C and UV-B on cytomorphology and water permeability of inner epidermal cells of Allium cepa

Changes of cytomorphology and water permeability of inner epidermal cells of Allium cepa L. cvs Spartan and Keep Well were investigated with the light microscope after irradiation with UV-C (254 nm) and UV-B (280 and 310 nm). The sequence of the investigated changes of viscosity, protoplasmic streaming, organelle shape and water permeability was the same with 254 as with 280 nm. although a higher dose of 280 nm was needed to produce the same biologically equivalent effect. However, when calculated as a percentage of the lethal dose, the initial doses that produced the effects were the same for 254 and 280 nm. No changes could he observed at the cellular level after the cells were irradiated with 310 nm. The lethal dose depended upon the time between irradiation and observation. At 254 nm it was 1.1 kJ m⁻² up to 1 h after irradiation and dropped to 860 J m⁻² when measured 24 and 48 h later. At 280 nm a dose of 2.8 kJ m⁻² killed the cells within I h while the dose needed after 24 and 48S h was 1.99 kJ m⁻². The minimum doses which caused the different cytomorphological effects did not depend upon the observation time. Normal cell structure and functions that were altered immediately alter irradiation did not recover. Doses that were not immediately effective alter irradiation caused no later damage. Doses which increased water permeability were much higher than doses which influenced cytomorphological parameters of the cell.     

The effect of low-intensity light from the red and far red regions of the spectrum on Escherichia coli

The effect of red and far red light having a low intensity on Escherichia coli growth was studied. The growth accelerated when the culture was irradiated with the light at a dose of 1--4 X 10(3) J/m2. When the light of the two spectral regions was used together, the effect depended on the dose and order of the irradiation. It is possible that receptors for red light and for far red light interact in E. coli cells.