Effects of Solar UV Radiation on Morphology and Photosynthesis of Filamentous Cyanobacterium Arthrospira platensis

To study the impact of solar UV radiation (UVR) (280 to 400 nm) on the filamentous cyanobacterium Arthrospira (Spirulina) platensis, we examined the morphological changes and photosynthetic performance using an indoor-grown strain (which had not been exposed to sunlight for decades) and an outdoor-grown strain (which had been grown under sunlight for decades) while they were cultured with three solar radiation treatments: PAB (photosynthetically active radiation [PAR] plus UVR; 280 to 700 nm), PA (PAR plus UV-A; 320 to 700 nm), and P (PAR only; 400 to 700 nm). Solar UVR broke the spiral filaments of A. platensis exposed to full solar radiation in short-term low-cell-density cultures. This breakage was observed after 2 h for the indoor strain but after 4 to 6 h for the outdoor strain. Filament breakage also occurred in the cultures exposed to PAR alone; however, the extent of breakage was less than that observed for filaments exposed to full solar radiation. The spiral filaments broke and compressed when high-cell-density cultures were exposed to full solar radiation during long-term experiments. When UV-B was screened off, the filaments initially broke, but they elongated and became loosely arranged later (i.e., there were fewer spirals per unit of filament length). When UVR was filtered out, the spiral structure hardly broke or became looser. Photosynthetic O₂ evolution in the presence of UVR was significantly suppressed in the indoor strain compared to the outdoor strain. UVR-induced inhibition increased with exposure time, and it was significantly lower in the outdoor strain. The concentration of UV-absorbing compounds was low in both strains, and there was no significant change in the amount regardless of the radiation treatment, suggesting that these compounds were not effectively used as protection against solar UVR. Self-shading, on the other hand, produced by compression of the spirals over adaptive time scales, seems to play an important role in protecting this species against deleterious UVR. Our findings suggest that the increase in UV-B irradiance due to ozone depletion not only might affect photosynthesis but also might alter the morphological development of filamentous cyanobacteria during acclimation or over adaptive time scales.     

Effects of Low Temperature, Light and O2 on Chilling-sensitive and -resistant Strains in Chlorella ellipsoidea

A low-temperature sensitive strain, Chlorella ellipsoidea Gerneck(IAM C-102), lost its chilling sensitivity during preservation.Cells of the original strain (low-temperature sensitive) andthe variant (low-temperature resistant) were both synchronouslygrown under a 14-hr light-10-hr dark regime. In the originalstrain, cells at the D-L stage (transient phase) were most sensitiveto a low temperature, whereas the variant cells were not damagedat any stage. During low-temperature treatment, the viability of D-L cellsin the sensitive strain decreased after a lag period of 1 hr.The O₂-uptake activity (respiration) showed the same behavioras the viability, whereas the O₂-evolution activity (photosynthesis)decreased from the start of chilling. In the resistant strain,only O₂ evolution decreased. The decreased activity was restoredwhen the chilled cells were incubated at 25°C. This restorationwas inhibited by oligomycin. Lowering the light intensity or eliminating O2 diminished thechilling injury of the sensitive strain. The results indicatethat the chilling injury of Chlorella results from the combinedeffects of low temperature, light and O₂. (Received September 26, 1980; Accepted March 23, 1981)     

Effect of Temperature on the Activity of Carboxylases in Tropical and Temperate Gramineae

Temperate Gramineae show maximal net photosynthesis at 20–5°C, whereas tropical Gramineae have maxima between 30 and35 °C. Moreover, it has been suggested that different carboxylationreactions are involved in the two groups. The present studyof the temperature dependance of in vitro ribulose-1,5- diphosphate(RuDP), and phosphopyruvate (PEP) carboxylases indicates thatthe two enzymes have clearly marked differences in temperaturesensitivity. RuDP carboxylase, present in the temperate andtropical species studied, showed maximal activity around 20–5°C except in Zea. By contrast, PEP carboxylase activityin all species was maximal between 30 and 35 °C. The dataimply that activity and temperature sensitivity of the relevantcarboxylase enzymes may well be a significant limiting factorin leaf photosynthesis, even at light saturation.     

Diverse Responses to UV-B Radiation and Repair Mechanisms of Bacteria Isolated from High-Altitude Aquatic Environments

Acinetobacter johnsonii A2 isolated from the natural community of Laguna Azul (Andean Mountains at 4,560 m above sea level), Serratia marcescens MF42, Pseudomonas sp. strain MF8 isolated from the planktonic community, and Cytophaga sp. strain MF7 isolated from the benthic community from Laguna Pozuelos (Andean Puna at 3,600 m above sea level) were subjected to UV-B (3,931 J m⁻²) irradiation. In addition, a marine Pseudomonas putida strain, 2IDINH, and a second Acinetobacter johnsonii strain, ATCC 17909, were used as external controls. Resistance to UV-B and kinetic rates of light-dependent (UV-A [315 to 400 nm] and cool white light [400 to 700 nm]) and -independent reactivation following exposure were determined by measuring the survival (expressed as CFU) and accumulation of cyclobutane pyrimidine dimers (CPD). Significant differences in survival after UV-B irradiation were observed: Acinetobacter johnsonii A2, 48%; Acinetobacter johnsonii ATCC 17909, 20%; Pseudomonas sp. strain MF8, 40%; marine Pseudomonas putida strain 2IDINH, 12%; Cytophaga sp. strain MF7, 20%; and Serratia marcescens, 21%. Most bacteria exhibited little DNA damage (between 40 and 80 CPD/Mb), except for the benthic isolate Cytophaga sp. strain MF7 (400 CPD/Mb) and Acinetobacter johnsonii ATCC 17909 (160 CPD/Mb). The recovery strategies through dark and light repair were different in all strains. The most efficient in recovering were both Acinetobacter johnsonii A2 and Cytophaga sp. strain MF7; Serratia marcescens MF42 showed intermediate recovery, and in both Pseudomonas strains, recovery was essentially zero. The UV-B responses and recovery abilities of the different bacteria were consistent with the irradiation levels in their native environment.     

Development in the Floating World: Defenses of Eggs and Embryos Against Damage from UV Radiation

Eggs and embryos of many aquatic organisms develop in the watercolumn and can experience ultraviolet radiation with potentiallydeleterious effects. This is especially vexing for floatingembryos that develop in the surface or neuston layer. Radiationdamage can be a particular problem for these embryos since thecell division cycle during the cleavage period is quite shortand often these cycles do not have mitotic checkpoints to insurefaithful transmission of DNA to the daughter cells. This couldresult in cell division with unrepaired DNA in the blastomeres,which could impact embryogenesis and the transmission of thegenome through the germ line. Described strategies to restrictradiation damage include mechanisms to limit oxidative damageand the use of sunscreens such as the mycosporines to curb radiationto sensitive targets. We describe a particularly ingenious useof sunscreens in the tunicate embryo, the use of extra-embryoniccells to shield the embryo from potentially harmful UV-A andUV-B radiation. We also raise questions regarding the natureof UV damage to embryos (is it DNA or also protein) and thecharacteristics of DNA repair in such embryos. It is likelythat unique mechanisms are present in floating embryos thatdevelop in this air-water interface to assure that cell andgenomic integrity are maintained in this challenging environment.     

Effects of Temperature on Photosynthesis by Maize and Wheat

Maize and wheat plants were grown in controlled environmentswith day temperatures of 13, 18, 23, or 28 ?C. Leaves from maizegrown at 23 ?C photosynthesized faster than leaves from maizegrown at 13 or 18 ?C and, except when measured at 28 ?C, fasterthan leaves from maize grown at 28 ?C;leaves of maize grownat13 ?C were yellow and photosynthesized at insignificant rates.Leaves from wheat grown at 18 ? or 13 ?C had faster rates ofphotosynthesis than leaves from wheat grown at 23 or 28 ?C.The best rates for maize were faster than the best rates forwheat when the measurements were made at 23 or 28 ?C but at13 or 18 ?C the best rates for maize were not significantlybetter than the best rates for wheat. Leaves of maize that developedin the environment with 23 ?C as the day temperature did notrapidly lose their green colour when transferred to the environmentwith the day temperature of 13 ?C and the rate of photosynthesisof these leaves did not decline rapidly. However, new leavesexpanding in the cooler conditions were yellow and not effectivein photosynthesis. At 13 or 18 ?C maize, a C4 plant, which photorespiresslowly, did not photosynthesize more effectively than wheat,which photorespires rapidly. The maize did not produce its mosteffective leaves at 13 or 18 ?C and its optimum temperaturefor photosynthesis was 23?C or higher. It may therefore be consideredill-adapted to the temperate climate.     

Gas Exchange of Algae: II. Effects of Oxygen, Helium, and Argon on the Photosynthesis of Chlorella pyrenoidosa

Changes in the oxygen partial pressure of air over the range of 8 to 258 mm of Hg did not adversely affect the photosynthetic capacity of Chlorella pyrenoidosa. Gas exchange and growth measurements remained constant for 3-week periods and were similar to air controls (oxygen pressure of 160 mm of Hg). Oxygen partial pressures of 532 and 745 mm of Hg had an adverse effect on algal metabolism. Carbon dioxide consumption was 24% lower in the gas mixture containing oxygen at a pressure 532 mm of Hg than in the air control, and the growth rate was slightly reduced. Oxygen at a partial pressure of 745 mm of Hg decreased the photosynthetic rate 39% and the growth rate 37% over the corresponding rates in air. The lowered metabolic rates remained constant during 14 days of measurements, and the effect was reversible after this time. Substitution of helium or argon for the nitrogen in air had no effect on oxygen production, carbon dioxide consumption, or growth rate for 3-week periods. All measurements were made at a total pressure of 760 mm of Hg, and all gas mixtures were enriched with 2% carbon dioxide. Thus, the physiological functioning and reliability of a photosynthetic gas exchanger should not be adversely affected by: (i) oxygen partial pressures ranging from 8 to 258 mm of Hg; (ii) the use of pure oxygen at reduced total pressure (155 to 258 mm of Hg) unless pressure per se affects photosynthesis, or (iii) the inclusion of helium or argon in the gas environment (up to a partial pressure of 595 mm of Hg).     

Effects of Light, Carbon Dioxide, and Temperature on Photosynthesis, Oxygen Inhibition of Photosynthesis, and Transpiration in Solanum tuberosum

Individual leaves of potato (Solanum tuberosum L. W729R), a C₃ plant, were subjected to various irradiances (400-700 nm), CO₂ levels, and temperatures in a controlled-environment chamber. As irradiance increased, stomatal and mesophyll resistance exerted a strong and some-what paralleled regulation of photosynthesis as both showed a similar decrease reaching a minimum at about 85 neinsteins·cm⁻²·sec⁻¹ (about ½ of full sunlight). Also, there was a proportional hyperbolic increase in transpiration and photosynthesis with increasing irradiance up to 85 neinsteins·cm⁻²·sec⁻¹. These results contrast with many C₃ plants that have a near full opening of stomata at much less light than is required for saturation of photosynthesis.     

夜间低温对不同光强下生长的两种热带树苗光合作用的影响

于雾凉季测定了叶片叶绿素荧光和气体交换参数、H2 O2 和丙二醛 (MDA)含量 ,探讨了 4～ 6℃夜间低温对 3种相对光强 (太阳光的 8%、2 5 %和 5 0 % )下生长的 2种山地雨林树苗光合作用的影响。夜间低温处理导致 3种光强下生长的 2种植物叶片日间和胁迫诱导的光抑制加剧 ,净光合速率 (Pn)和光呼吸速率降低 ,H2 O2 和MDA含量升高。生长环境光强升高可加剧夜间低温的效应 ,弱光下 2种植物受夜间低温影响较小 ,间接表明雾使光强减弱可缓解自然夜温降低对西双版纳热带植物的危害。处理期间滇南插柚紫Pn 主要受气孔限制 ,滇南红厚壳Pn 降低与活性氧增加引起的羧化效率降低有关 ,两种植物Pn 的降低均与光抑制关系不大。夜间低温后滇南红厚壳气孔导度降低较少 ,H2 O2 和MDA含量较高 ,光抑制较重 ,5 0 %相对光强下其未做夜间低温处理的对照植株发生了胁迫诱导的光抑制 ,表明它对夜间低温较敏感。     

Extremophilic Acinetobacter Strains from High-Altitude Lakes in Argentinean Puna: Remarkable UV-B Resistance and Efficient DNA Damage Repair

High-Altitude Andean Lakes (HAAL) of the South American Andes are almost unexplored ecosystems of shallow lakes. The HAAL are recognized by a remarkably high UV exposure, strong changes in temperature and salinity, and a high content of toxic elements, especially arsenic. Being exposed to remarkably extreme conditions, they have been classified as model systems for the study of life on other planets. Particularly, Acinetobacter strains isolated from the HAAL were studied for their survival competence under strong UV-B irradiation. Clinical isolates, Acinetobacter baumannii and Acinetobacter johnsonii, served as reference material. Whereas the reference strains rapidly lost viability under UV-B irradiation, most HAAL-derived strains readily survived this exposure and showed less change in cell number after the treatment. Controls for DNA repair activity, comparing dark repair (DR) or photo repair (PR), gave evidence for the involvement of photolyases in the DNA repair. Comparative measurements by HPLC-mass spectrometry detected the number of photoproducts: bipyrimidine dimers under both PR and DR treatments were more efficiently repaired in the HAAL strains (up to 85?% PR and 38?% DR) than in the controls (31?% PR and zero DR ability). Analysis of cosmid-cloned total genomic DNA from the most effective DNA-photorepair strain (Ver3) yielded a gene (HQ443199) encoding a protein with clear photolyase signatures belonging to class I CPD-photolyases. Despite the relatively low sequence similarity of 41?% between the enzymes from Ver3 and from E. coli (PDB 1DNPA), a model-building approach revealed a high structural homology to the CPD-photolyase of E. coli.     

Nitrate Nutrition and Temperature Effects on Wheat: Photosynthesis and Photorespiration of Leaves

Lawlor, D. W., Boyle, F. A., Young, A. T., Keys, A. J. and Kendall,A. C. 1987. Nitrate nutrition and temperature effects on wheat:photosynthesis and photorespiration of leaves.—J. exp.Bot. 38: 393–408. Photosynthetic and photorespiratory carbon dioxide exchangeby the third leaf of spring wheat (Triticum aestivum cv. Kolibri),was analysed for plants grown at 13/10 °C (day/night temperature)and 23/18 °C with two rates of nitrate fertilization (abasal rate, — N, and a 4-fold larger rate, +N) and, insome experiments, with two photon fluxes. Net photosynthesiswas greatest at the time of maximum lamina expansion, and forleaves grown with additional nitrate. Maximum rate of photosynthesis,carboxylation efficiency and photochemical efficiency at maturitywere slightly decreased by nitrate deficiency but photosystemactivity was similar under all conditions. As leaves aged, photosynthesisand photochemical efficiency decreased; carboxylation efficiencydecreased more than photochemical efficiency particularly withbasal nitrate. Low oxygen increased the carboxylation and photochemicalefficiencies, and increased the maximum rate of assimilationby a constant proportion in all treatments. Photorespiration,measured by CO₂ efflux to CO₂-free air, by ¹⁴CO₂ uptake, andfrom compensation concentration, was proportional to assimilationin all treatments. It was greater, and formed a larger proportionof net photosynthesis, when measured in warm than in cold conditionsbut was independent of growth conditions. Assimilation was relatedto RuBPc-o activity in the tissue. Relationships between photosynthesis,photorespiration and enzyme complement are discussed. Key words: Wheat, leaves, nitrate nutrition, temperature effect, photosynthesis, photorespiration     

Growth Response of a Chrysanthemum Crop to the Environment. III, Effects of Radiation and Temperature on Dry Matter Partitioning and Photosynthesis

Vegetative crops of chrysanthemum were grown for 5 or 6 weekperiods in daylit assimilation chambers. Crop responses to differentradiation levels and temperatures were analysed into effectson dry matter partitioning, specific leaf area, leaf photosynthesisand canopy light interception. The percentage of newly formed dry matter partitioned to theleaves was almost constant, although with increasing radiationor decreasing temperature, a greater percentage of dry matterwas partitioned to stem tissue at the expense of root tissue.There was a positive correlation between the percentage of drymatter in shoot material and the overall carbon: dry matterratio. Canopy photosynthesis was analysed assuming identical behaviourfor all leaves in the crop. Leaf photochemical efficiency wasonly slightly affected by crop environment. The rate of grossphotosynthesis per unit leaf area at light saturation, P_A (max),increased with increasing radiation integral, but the same parameterexpressed per unit leaf dry matter, P_w (max) was almost unaffectedby growth radiation. In contrast, P_A (max) was hardly affectedby temperature but P_w (max) increased with increasing growthtemperature. This was because specific leaf area decreased withdecreasing temperature and increased with decreasing radiation.There was a positive correlation between canopy respirationintegral and photosynthesis integral, and despite a four-foldchange in crop mass during the experiments, the maintenancecomponent of canopy respiration remained small and constant. Canopy extinction coefficient showed no consistent variationwith radiation integral but was negatively correlated with temperature.This decrease in the efficiency of the canopy at interceptingradiation exactly cancelled the increase in specific carbonassimilation rate that occurred with increasing growth temperature,giving a growth rate depending solely on the incident lightlevel. Chrysanthemum, dry matter partitioning, photosynthesis, specific leaf area     

Effects of Temperature and CO2 Concentration on Induction of Carbonic Anhydrase and Changes in Efficiency of Photosynthesis in Chlorella vulgaris 11h

The increase in carbonic anhydrase (CA) activity and the decreasein apparent K_m(CO₂) for photosynthesis induced by reducing CO₂concentration during the growth of Chlorella vulgaris 11h cellswere followed under different temperatures. Both changes wereaccelerated by raising the temperature and reached an optimumat 32–37?C. When the CO₂ concentration was lowered from3 to 0.04%, the rate of photosynthetic O₂ evolution at limitingCO₂ concentrations increased and reached a stationary levelafter 3 h. Under such conditions, the concentration of CO₂ dissolvedin the algal suspension decreased logarithmically (t_1/2=10 min)and reached a concentration in equilibrium with 0.04% CO₂ inair after ca. 2 h. When high-CO₂ cells grown with 3% CO₂ in air were transferredto various lower CO₂ concentrations, CA activity and apparentK_m(CO₂) for photosynthesis changed depending on the CO₂ concentration.The CO₂ concentration which gives one-half the maximum valuefor K_m(CO₂) and one-half minimum value foi CA activities wasabout 0.5%. The inverse relationship observed for the changesin CA activity and the affinity for CO₂ in photosynthesis supportsthe theory that CA loweres the apparent K_m(CO₂) for photosynthesisin Chlorella vulgaris 11h. (Received August 27, 1984; Accepted February 8, 1985)     

153Invasive Macroalgae on Tropical Reefs: Impacts, Interactions, Mechanisms and Management

Histories, patterns of introduction, management of impacts and predictable futures? Ecological impacts of weedy introduced and native marine algae have set Hawai'i apart from elsewhere in the tropics and offers a new show case for macroalgal blooms. Partly because of our isolation, impacts of non-indigenous species have been clearly identified, in some cases almost as quickly as introductions have occurred to Hawai'i. While hull fouling or intentional introductions may have been initial mechanisms for macroalgal introductions, spread among the Hawaiian Islands is not necessarily linked to the vector for arrival. Further, impacts of non-indigenous species are also not fully predictable, prior to introduction. This situation leads to challenging gaps in management strategies because few generalizations about the roles of nutrients or herbivory as drivers for macroalgal blooms can be supported at this time. Weedy native species represent a wide range of alternate impacts with other apparent combinations of forcing functions. Case histories for the most significant non-indigenous and weedy native algae will be presented with emphasis on potential new criteria to assess ecological impacts and provide resource biologists with critical new tools for the management of reef ecosystems.     

Effects of Visible Light and UV Radiation on Photosynthesis in a Population of a Hot Spring Cyanobacterium, a Synechococcus sp., Subjected to High-Temperature Stress

Assays of photosynthesis were conducted with a biofilm population of a cyanobacterium, a Synechococcus sp., growing at ~70°C in a Yellowstone National Park hot spring to test whether cells growing near the upper temperature limit of photosynthetic life are optimally adapted to their mean environmental temperature. Cell suspensions were assayed at 70, 65, and 55°C while being simultaneously exposed to modified solar environments, including reduction of total irradiance and exclusion of UV radiation. Carbon fixation was greatest at 65°C, while 70 and 55°C were always supraoptimal and suboptimal for photosynthesis, respectively. The degree of temperature stress was dependent upon light intensity, and this light-dependent temperature effect may involve both reduced quantum efficiency at subsaturating irradiances and a lower saturating irradiance at both supraoptimal and suboptimal temperatures. The Synechococcus sp. was also more susceptible to UV inhibition of photosynthesis at nonoptimal temperatures. These results suggest that this population is persisting at a nearly lethal temperature and is consequently subject to greater damage by both visible and UV radiation, but it is speculated that these cells may be avoiding competition with other photoautotrophs under these nonoptimal conditions. In separate experiments monitoring diurnal patterns of photosynthesis, cells exhibited peak productivity during the morning, followed by an afternoon decline. No recovery of photosynthesis was observed during the remaining daytime, and carbon fixation was always UV inhibited under conditions of photosynthetically saturating light.     

Increased Drought Impacts on Temperate Rainforests from Southern South America: Results of a Process-Based,Dynamic Forest Model

Increased droughts due to regional shifts in temperature and rainfall regimes are likely to affect forests in temperate regions in the coming decades. To assess their consequences for forest dynamics, we need predictive tools that couple hydrologic processes, soil moisture dynamics and plant productivity. Here, we developed and tested a dynamic forest model that predicts the hydrologic balance of North Patagonian rainforests on Chiloé Island, in temperate South America (42°S). The model incorporates the dynamic linkages between changing rainfall regimes, soil moisture and individual tree growth. Declining rainfall, as predicted for the study area, should mean up to 50% less summer rain by year 2100. We analysed forest responses to increased drought using the model proposed focusing on changes in evapotranspiration, soil moisture and forest structure (above-ground biomass and basal area). We compared the responses of a young stand (YS, ca. 60 years-old) and an old-growth forest (OG, >500 years-old) in the same area. Based on detailed field measurements of water fluxes, the model provides a reliable account of the hydrologic balance of these evergreen, broad-leaved rainforests. We found higher evapotranspiration in OG than YS under current climate. Increasing drought predicted for this century can reduce evapotranspiration by 15% in the OG compared to current values. Drier climate will alter forest structure, leading to decreases in above ground biomass by 27% of the current value in OG. The model presented here can be used to assess the potential impacts of climate change on forest hydrology and other threats of global change on future forests such as fragmentation, introduction of exotic tree species, and changes in fire regimes. Our study expands the applicability of forest dynamics models in remote and hitherto overlooked regions of the world, such as southern temperate rainforests.     

The Effects of Streptomycin, Desiccation, and UV Radiation on Ice Nucleation by Pseudomonas viridiflava

Streptomycin (100 micrograms per milliliter), desiccation (over CaSO₄), and ultraviolet radiation (4500 microwatts per square centimeter at 254 nanometers for 15 minutes) reduced ice nucleation activity by Pseudomonas viridiflava strain W-1 as determined by freezing drops of the bacterial suspensions. Highest residual ice nucleation activity by dead cells was obtained by desiccation, although no freezing above −3.5°C was detected. The rate and extent of loss of ice nucleation activity following streptomycin and ultraviolet treatment was affected by preconditioning temperature. At 21°C and above, loss of activity by dead cells was rapid and irreversible.     

Differential Habitat Selection by Pygmy Grasshopper Color Morphs; Interactive Effects of Temperature and Predator Avoidance

Habitat selection behavior is affected by complex interplays between competing requirements. Here we combine field observations with laboratory experiments to examine how thermal benefits and predator avoidance influences habitat selection by different color morphs of the pygmy grasshopper Tetrix undulata. The composition of substrate types and surface temperatures in areas selected by free-ranging individuals did not reflect relative availability, and varied among morphs and sexes. Surface temperatures of selected habitats deviated less from the range of preferred body temperatures than would result from a random utilization of surface temperatures, suggesting that grasshoppers selected habitats with thermal properties which were suitable for maintaining preferred body temperatures. The thermal property of habitats occupied by different color morphs suggests that darker morphs (which absorb more solar radiation) selected cooler habitats to avoid overheating. Dissimilarities in substrate use among color morphs in the field and laboratory emphasize a role also of predator avoidance by background matching for habitat choice. The degree of habitat selectivity was lowest in the striped morph, supporting the notion that a disruptive color pattern may constitute a solution to the trade-off between relative crypsis in different visual backgrounds. Finally, individuals modified their habitat use when subjected to elevated risk of predation, showing that habitat choice is governed by conflicting priorities. Collectively, our findings suggest that, as a result of direct and indirect effects of coloration on performance, alternative color morphs use different solutions to the trade-off between competing requirements. Our results also lend support to the notion that relative fitness of alternative color morphs and sexes may be dependent on microhabitat selection, as predicted by the theory of multiple niche polymorphisms.     

Limits to Diffusive O2 Transport: Flow,Form, and Function in Nudibranch Egg Masses from Temperate and Polar Regions

Background

Many aquatic animals enclose embryos in gelatinous masses, and these embryos rely on diffusion to supply oxygen. Mass structure plays an important role in limiting or facilitating O₂ supply, but external factors such as temperature and photosynthesis can play important roles as well. Other external factors are less well understood.

Methodology/Principal Findings

We first explored the effects of water flow on O₂ levels inside nudibranch embryo masses and compared the effects of flow on masses from temperate and polar regions. Water flow (still vs. vigorously bubbled) had a strong effect on central O₂ levels in all masses; in still water, masses were considerably more hypoxic than in bubbled water. This effect was stronger in temperate than in polar masses, likely due to the increased metabolic demand and O₂ consumption of temperate masses. Second, we made what are to our knowledge the first measurements of O₂ in invertebrate masses in the field. Consistent with laboratory experiments, O₂ in Antarctic masses was high in masses in situ, suggesting that boundary-layer effects do not substantially limit O₂ supply to polar embryos in the field.

Conclusions/Significance

All else being equal, boundary layers are more likely to depress O₂ in masses in temperate or tropical regions; thus, selection on parents to choose high-flow sites for mass deposition is likely greater in warm water. Because of the large number of variables affecting diffusive O₂ supply to embryos in their natural environment, field observations are necessary to test hypotheses generated from laboratory experiments and mathematical modeling.     

Potential Repair of Escherichia coli DNA following Exposure to UV Radiation from Both Medium- and Low-Pressure UV Sources Used in Drinking Water Treatment

The increased use of UV radiation as a drinking water treatment technology has instigated studies of the repair potential of microorganisms following treatment. This study challenged the repair potential of an optimally grown nonpathogenic laboratory strain of Escherichia coli after UV radiation from low- and medium-pressure lamps. Samples were irradiated with doses of 5, 8, and 10 mJ/cm² from a low-pressure lamp and 3, 5, 8, and 10 mJ/cm² from a medium-pressure UV lamp housed in a bench-scale collimated beam apparatus. Following irradiation, samples were incubated at 37°C under photoreactivating light or in the dark. Sample aliquots were analyzed for up to 4 h following incubation using a standard plate count. Results of this study showed that E. coli underwent photorepair following exposure to the low-pressure UV source, but no repair was detectable following exposure to the medium-pressure UV source at the initial doses examined. Minimal repair was eventually observed upon medium-pressure UV lamp exposure when doses were lowered to 3 mJ/cm². This study clearly indicates differences in repair potential under laboratory conditions between irradiation from low-pressure and medium-pressure UV sources of the type used in water treatment.