Disruption of cytoplasmic microtubules by ultraviolet radiation.

Ultraviolet (UV) irradiation of cultured human skin fibroblasts causes the disassembly of their microtubules. Using indirect immunofluorescence microscopy, we have now investigated whether damage to the microtubule precursor pool may contribute to the disruption of microtubules. Exposure to polychromatic UV radiation inhibits the reassembly of microtubules during cellular recovery from cold treatment. In addition, the ability of taxol to promote microtubule polymerization and bundling is inhibited in UV-irradiated cells. However, UV irradiation of taxol-pretreated cells or in situ detergent-extracted microtubules fails to disrupt the microtubule network. These data suggest that damage to dimeric tubulin, or another soluble factor(s) required for polymerization, contributes to the disassembly of microtubules in UV-irradiated human skin fibroblasts.     

Stomatal closure by ultraviolet radiation

The effect of ultraviolet radiation (UV) (255–325 nm) on stomatal closure was investigated on tef [ Eragrostis tef (Zucc) Trotter] in the presence of white light (ca 50 ·mol m⁻² s⁻¹). The action spectrum showed that UV (ca 2 ·mol m⁻² s⁻¹, half band width about 10 nm) of 285 nm or shorter wavelengths was very efficient in causing stomatal closure. The effectiveness decreased sharply towards longer wavelengths. Radiation of 313 nm or longer wavelengths was practically without effect. Increasing UV intensity increased stomatal resistance. When stronger white light (5 to 9 times stronger than the one used during irradiation) was administered, stomates re-opened rapidly irrespective of whether the UV was on or off, although a subsequent gradual closing tendency was observed when the UV was on.     

Ammonia nitrogen and inorganic phosphorus excretion by the planktonic rotifers

Two series of experiments were carried out to determine the relation of the rate of phosphorus and nitrogen excretion by the planktonic rotifers to ambient temperature and individual body weights of these animals. The following formulas describing this relation were obtained: E_P=0.0154 W^?1.27 e^0.096T E_N=0.0879 W^?1.01 e^{0.088 T}, where E_P and E_N denote the rate of P and N excretion, respectively, in µg · mg dry wt^?1 · h^?1, W is body weight in µg dry weight, and T is temperature in °C.     

Photoinactivation of cellular catalase by ultraviolet radiation

Summary

Photoinactivation of catalase is found to be similar in solution and in human normal skin fibroblasts exposed to ultraviolet B, ultraviolet A and near visible light, and the kinetics of such photoinactivation obey first order processes. The action spectrum, measured for the first time in cells, suggests that catalase photoinactivation in solution and in cells proceeds via similar routes. In both systems, no protective effect was observed with diethyldithiocarbamate, a superoxide dismutase inhibitor, with desferrioxamine, an iron chelator which impedes the production of hydroxyl radical via the Fenton reaction, and with vitamin E which scavenges peroxyl radical to protect against membrane peroxidative process. While the absence of protection by these inhibitors may be anticipated for the photoinactivation of catalase in solution, the lack of effect in cells suggests that reactive oxygen species produced by endogenous photosensitization are not responsible for the enzyme inactivation. Moreover, the already established protective effect of ethanol in solution is also observed in cells, supporting the view that photoinactivation in solution and in cells is due to the same primary events.     

Inactivation of Neurospora conidia by ultraviolet radiation

The inactivation of Neurospora conidia by ultraviolet radiation is a consequence of the inactivation of the nuclei. The nuclei exhibit a kinetics of inactivation which is first order with respect to the number of (viable) nuclei. Arguments based on the efficiency of inactivation indicate that only quanta absorbed within a nucleus can lead to its inactivation.There are at least two sets of inactivation processes. One involves the production of lethal mutations, the other is a non-genetic (not inheritable) process. The two processes are apparently intimately connected: they yield the same action spectrum and the effects of each are reduced by photo reactivation. The assumption that the two processes are independent leads to predictions which are at variance with the observed dependence of the frequency of lethal mutations on dose of ultraviolet radiation.     

Inactivation of Candida albicans by ultraviolet radiation

Summary Inactivation of Candida albicans by ultraviolet (uv) light is markedly dependent upon (a) the cell division stage and (b) the nutrition and growth temperatures of cells both before and after irradiation. Cells grown at 37°C after irradiation show lower survivals than those grown at 25°C. At either recovery temperature, cells which had been cultured before irradiation at 37°C are able to sustain less uv damage prior to inactivation than those cultured at 25°C. The radiosensitivities of budding and non-budding cells are the same when survivals are scored at 25°C; at low uv dosages, cells show slightly poorer recoveries on enriched medium than on minimal medium whereas at higher dosages, their recoveries on both kinds of media are equivalent. In contrast, at 37°C, uv treated non-budding cells are much more susceptible to inactivation than budding cells; non-budding cells also express much poorer recovery on enriched medium than on minimal medium at 37°C whereas budding cells survive equally well on either medium. Though non-budding cells grown for irradiation on minimal or enriched media exhibit the same radiosensitivites, budding cells grown for irradiation on enriched medium are more susceptible to inactivation at 37°C than those grown on minimal medium.The particularly poor recovery by irradiated non-budding cells at 37°C is correlated with their unique tendency to undergo a transitory filamentation when initiating growth at that temperature. Evidence is presented that neither the filamentous growth per se nor the temporary inhibition of cell division associated with filamentation causes the poor recovery. Furthermore, while irradiated non-budding cells at 37°C exhibit singular susceptibility to inhibition of recovery by metabolic antagonists which disturb protein synthesis, the course of their filamentous growth is not affected by such agents. It is concluded that recovery from irradiation and the instigation of cytokinesis by non-budding cells of C. albicans result from different metabolic processes which may be related through a common temperature sensitive step. C. albicans does not photoreactivate and observations on recovery by cells prevented from undergoing immediate postirradiation replication do not indicate the existence of a system for dark repair of DNA damage comparable to that occurring in bacteria. Difficulties attending a valid demonstration of DNA dark repair in yeasts are discussed.     

The effects of ultraviolet radiation on the planktonic community of a shallow, eutrophic estuary: results of mesocosm experiments

This paper describes the results of pelagic mesocosm experiments designed to test the effects of enhanced and reduced ultraviolet radiation (UV) on the planktonic community of a Baltic Sea estuary. The Darss-Zingst estuary consists of a series of brackish lagoons with high concentrations of chlorophyll and dissolved organic matter. The shallow depth of the estuary ensures that organisms in the water are regularly exposed to high levels of photosynthetically active radiation (PAR) and UV. During the summer of 1995 and 1996, four 1-m³ mesocosms were filled with water from the mid-point of the estuary. Each compartment was equipped with a pump to simulate natural rates of wind-induced vertical mixing. The mesocosms were hung in the estuary from a floating raft and were shielded from above by filters to give the spectral treatments PAR only, PAR+UV-A, and PAR+UV-A+UV-B. Enhanced levels of UV-B, i.e. twice that of midday sunlight, were provided in a further treatment by artificial sunlamps. Experiments were conducted for periods of 3–14 days. No significant effects of enhanced or reduced UV-B were observed on chlorophyll a concentrations or photosynthetic performance, although the PAR-only treatment did show higher final chlorophyll concentrations in two of the trials. Phytoplankton pigment composition was measured by in vivo absorption and fluorescence excitation spectra, and was similar in all mesocosm treatments indicating that there were no major differences in functional group composition. Bacterial secondary production rates as measured by thymidine incorporation increased with time in all mesocosms, probably due to enhanced production of phytoplankton exudate. There was evidence for a small depression of secondary production by enhanced UV-B, but only on certain days. Microzooplankton generally increased in all mesocosms to population densities higher than those observed in the estuary, and tended to reach higher final values in the mesocosms exposed to UV. It is concluded that vertical mixing which reduces the residence time of planktonic organisms in the surface layers, and high concentrations of chromophoric, dissolved organic matter, which greatly reduce the penetration of UV-B, combined to protect the planktonic community from UV-B damage. Received in revised form: 5 June 2000 Electronic Publication     

Enhancement of photosynthesis in Sorghum bicolor by ultraviolet radiation

We assessed the influence of ultraviolet radiation (UV) on net photosynthetic CO₂ assimilation rate (P_n) in Sorghum bicolor, with particular attention to examining whether UV can enhance P_n via direct absorption of UV and absorption of UV‐induced blue fluorescence by photosynthetic pigments. A polychromatic UV response spectrum of leaves was constructed by measuring P_n under different UV supplements using filters that had sharp transmission cut‐offs from 280 to 382 nm, against a background of non‐saturating visible light. When the abaxial surface was irradiated, P_n averaged 4.6% higher with the UV supplement that cut‐off UV at 311 nm, compared to lower and higher UV wavelength supplements. This former supplement differed from higher wavelength supplements by primarily providing more UV between 320 and 350 nm. To assess the possibility of direct absorption of UV by photosynthetic pigments, we measured the absorbance of extracted chlorophylls. Chlorophyll a had absorbance peaks at 340 and 389 nm that were 49 and 72% of that at the sorét peak. Chlorophyll b had absorbance peaks at 315 and 346 nm that were both 35% of that at the sorét peak. Since the epidermis transmits some UV, the strong UV absorbance of chlorophyll implies a potential role for irradiance beyond the bounds of the conventionally defined photosynthetically active radiation waveband (400–700 nm). To assess the role of absorption of UV‐induced blue fluorescence, we measured the UV‐induced fluorescence excitation and emission spectra of leaves. Abaxial excitation peaked at 328 nm, while emission peaked at 446 nm. In this analysis, we used our abaxial fluorescence excitation spectrum and the UV photosynthetic inhibition spectrum of Caldwell et al. (1986) to weight the UV irradiance with each cut‐off filter, thereby estimating the potential contribution of UV‐induced blue fluorescence to photosynthesis and the inhibitory effects of UV irradiance on photosynthesis, respectively. With a non‐saturating visible background, we estimate that the absorption of UV‐induced blue fluorescence and the direct absorption of UV by photosynthetic pigments maximally enhanced photosynthesis by about 1% each with the UV supplement that cut‐off UV at 311 nm. We suggest that a portion of the incident UV on the S. bicolor leaves was used to drive photosynthesis.     

Systemic suppression of contact hypersensitivity by ultraviolet b radiation or methoxsalen/ultraviolet a radiation in the guinea pig

Treatment of strain 2 guinea pigs with ultraviolet b (uvb) (280-320 nm) radiation or methoxsalen, followed by ultraviolet a (uva) (320-400 nm) radiation, decreased the contact hypersensitivity (CHS) reaction to sensitizing agents applied subsequently to unirradiated sites. The decreased reactivity could be transferred to syngeneic animals and appeared to be caused by antigen-specific suppressor T lymphocytes. Ultraviolet b irradiation of sensitized animals did not affect elicitation of CHS in unirradiated skin.     

Sensitivity of carcinogen-treated DNA to inactivation by ultraviolet radiation

The DNA of bacteriophage SPO2c12 was treated with methylmethane sulfonate (MMS), beta-propiolactone (BPL), 2-anthramine (AA) or benzo[a]pyrene (BP) and then exposed to 254-nm radiation. Competent Bacillus subtilis host cells were transfected with DNA subjected to the carcinogen-UV treatment or with DNA treated with carcinogen only. Survival curves were obtained for loss of plaque-forming ability as a function of UV dose. The UV sensitivity of DNA treated with MMS, BPL or AA was not significantly different from that of untreated DNA. The results indicate that in competent B. subtilis the pathways for repair of alkylating agent damage and for repair of UV damage are probably different.     

拟除虫菊酯类农药降解菌的紫外线诱变

拟除虫菊醑类农药降解菌阴沟肠杆菌(Enterobacter cloacap)w10j15菌株经紫外线诱变后,筛选出突变株55株。分别在30℃,转速180rpm条件下培养3d,测降解力,获得正突变菌株6株,经加药普通斜面传种10代,2株(UW19,UW2)降解力保持稳定。降解力较强的UW19对联苯菊醑、甲氰菊醑、氯氰菊醑的降解率分别达70．40％、84．04％、70．87％,比出发菌株降解率提高了近20％;UW2也比出发菌株提高了约10％的降解率。