Photosynthetic and oxidative stress in the green alga Dunaliella tertiolecta: The effects of UV-B and UV-A radiation

The penetration of ultraviolet-B (UV-B; 290-320 nm) into the biosphere has increased in response to decreased stratospheric ozone. As a consequence, significant attempts have been made to elucidate the effects of UV-B radiation on primary producers such as phytoplankton and plants. Considerably less effort has been devoted to describing the role played by ultraviolet-A (UV-A; 320-400 nm) radiation, which is not attenuated by stratospheric ozone. The present work details the independent and combined effects of UV-B and UV-A radiation on photosynthetic and oxidative stress responses using the unicellular green alga Dunaliella tertiolecta as a model organism. A UV-B spectral profile comparable to natural solar irradiance was produced in the laboratory by filtering UV-B lamp emissions with a novel liquid urate solution (UA) and compared against the conventionally used cellulose acetate (CA) filter. Cells growing at 100, 200 or 600 mumol photons m -2s-1 photosynthetically active radiation (PAR) were exposed to 12-hour UV-B (6 mumol photons m-2s-1), UV-A (60 mumol photons m-2s-1) or UV-B + UV-A (6 + 60 mumol photons m-2s-1) radiation treatments after which, photosynthesis, fluorescence parameters, D1 protein contents and antioxidant enzyme activities were recorded. In almost all cases, the physiology of UA cultures remained comparable to controls, white CA cultures suffered declines in photosynthesis and D1 protein content plus elevated antioxidant enzyme activities. UV-B: PAR ratios comparable to solar irradiance reduced UV-B induced photodamages, highlighting the significance of properly balanced irradiance environments within laboratory studies. Regardless of the PAR level applied, exposure to UV-A radiation resulted in acute photosynthetic and oxidative stress, which remained unchanged following the addition of UV-B flux. The findings of this study suggest that exposure to UV-A (and not UV-B) causes the direct impairment of photosynthesis and increased oxidative stress within plant cells. It is therefore recommended that laboratory based UV studies employ the use of UA filters and UV: PAR ratios that correspond to solar flux. Lastly, the discovery of least two ascorbate peroxidase (APX) isoforms suggests that like higher plants, green algae also possess APX isoenzymes. This is the first report documenting the presence of multiple APX isoforms within green algae

High CO2 decreases the long-term resilience of the free-living coralline algae Phymatolithon lusitanicum

Maerl/rhodolith beds are protected habitats that may be affected by ocean acidification (OA), but it is still unclear how the availability of CO2 will affect the metabolism of these organisms. Some of the inconsistencies found among OA experimental studies may be related to experimental exposure time and synergetic effects with other stressors. Here, we investigated the long-term (up to 20months) effects of OA on the production and calcification of the most common maerl species of southern Portugal, Phymatolithon lusitanicum. Both the photosynthetic and calcification rates increased with CO2 after the first 11months of the experiment, whereas respiration slightly decreased with CO2. After 20months, the pattern was reversed. Acidified algae showed lower photosynthetic and calcification rates, as well as lower accumulated growth than control algae, suggesting that a metabolic threshold was exceeded. Our results indicate that long-term exposure to high CO2 will decrease the resilience of Phymatolithon lusitanicum. Our results also show that shallow communities of these rhodoliths may be particularly at risk, while deeper rhodolith beds may become ocean acidification refuges for this biological community.Fundacao para a Ciencia e a Tecnologia [PTDC/MAR/115789/2009, SFRH/BD/76762/2011

Comparison of extraction methods for selected carotenoids from macroalgae and the assessment of their seasonal/spatial variation

peer-reviewedNatural bioactives are an excellent source of carotenoids for the production of nutraceuticals, functional foods and food additives. The extraction efficiencies of solid-liquid extraction (SLE), supercritical CO2, supercritical CO2 with ethanol as co-solvent for the recovery of the carotenoids, xanthophyll and fucoxanthin, from two brown macroalgae Fucus serratus and Laminaria digitata were explored. The extraction efficiency was measured using both purity and yield of target compounds. Solid liquid extraction. (hexane/acetone (70:30) at 50 degrees C for 24 h produced the greatest yield of carotenoid rich extracts from F. serratus. Optimal conditions in terms of carotenoid yield using supercritical CO2 were 50 degrees C, 300 Atm with an extraction time of 60 min. SCO2 yielded a higher purity of fucoxanthin while SLE resulted in a higher purity of xanthophyll. Seasonal/spatial variation based on the purity and yield was also investigated to provide valuable information on optimal harvest time for these compounds. (C) 2016 Elsevier Ltd. All rights reserved.ACCEPTEDpeer-reviewe

Pyogenic spondylitis

Pyogenic spondylitis is a neurological and life threatening condition. It encompasses a broad range of clinical entities, including pyogenic spondylodiscitis, septic discitis, vertebral osteomyelitis, and epidural abscess. The incidence though low appears to be on the rise. The diagnosis is based on clinical, radiological, blood and tissue cultures and histopathological findings. Most of the cases can be treated non-operatively. Surgical treatment is required in 10–20% of patients. Anterior decompression, debridement and fusion are generally recommended and instrumentation is acceptable after good surgical debridement with postoperative antibiotic cover

Solar ultraviolet radiation and ozone depletion-driven climate change: Effects on terrestrial ecosystems

In this assessment we summarise advances in our knowledge of how UV-B radiation (280-315 nm), together with other climate change factors, influence terrestrial organisms and ecosystems. We identify key uncertainties and knowledge gaps that limit our ability to fully evaluate the interactive effects of ozone depletion and climate change on these systems. We also evaluate the biological consequences of the way in which stratospheric ozone depletion has contributed to climate change in the Southern Hemisphere. Since the last assessment, several new findings or insights have emerged or been strengthened. These include: (1) the increasing recognition that UV-B radiation has specific regulatory roles in plant growth and development that in turn can have beneficial consequences for plant productivity via effects on plant hardiness, enhanced plant resistance to herbivores and pathogens, and improved quality of agricultural products with subsequent implications for food security; (2) UV-B radiation together with UV-A (315-400 nm) and visible (400-700 nm) radiation are significant drivers of decomposition of plant litter in globally important arid and semi-arid ecosystems, such as grasslands and deserts. This occurs through the process of photodegradation, which has implications for nutrient cycling and carbon storage, although considerable uncertainty exists in quantifying its regional and global biogeochemical significance; (3) UV radiation can contribute to climate change via its stimulation of volatile organic compounds from plants, plant litter and soils, although the magnitude, rates and spatial patterns of these emissions remain highly uncertain at present. UV-induced release of carbon from plant litter and soils may also contribute to global warming; and (4) depletion of ozone in the Southern Hemisphere modifies climate directly via effects on seasonal weather patterns (precipitation and wind) and these in turn have been linked to changes in the growth of plants across the Southern Hemisphere. Such research has broadened our understanding of the linkages that exist between the effects of ozone depletion, UV-B radiation and climate change on terrestrial ecosystems

Seasonal effects of sun exposure and emersion on intertidal seaweed physiology: Fluctuations in antioxidant contents, photosynthetic pigments and photosynthetic efficiency in the red alga Porphyra umbilicalis Kutzing (Rhodophyta, Bangiales)

There is a great deal of speculation regarding the physiological and biochemical mechanisms that give certain seaweed species the ability to colonize the intertidal zone. Frequent exposure to ambient temperatures and high irradiance levels in addition to dehydration during tidal emersion generates acute physiological stress. The ability of seaweeds like Porphya to overcome these challenges and survive in such a harsh environment has been linked to elevated reactive oxygen metabolism. The current study focused on measuring seasonal changes in antioxidant enzymes plus alterations in pigment contents and photosynthetic efficiency of P. umbilicalis plants found growing in the uppermost intertidal zone. Our results suggest that F. umbilicalis exhibits increased antioxidant metabolism, which could contribute to its success in colonizing such a stressful habitat. Elevated levels of glutathione reductase GTR, catalase and carotenoid contents during emersion suggested heightened protection against reactive oxygen species ROS damage is a necessary attribute for species in the upper intertidal regions. This hypothesis was further strengthened by the finding that the greatest antioxidant increases were observed during summer months when irradiance levels and temperatures were at their peak. Winter emersion did not elicit the same physiological response, as antioxidant levels were similar in submersed and emersed plants. For the most part, photosynthetic pigments were largely affected by sun exposure and less by emersion stress. Shaded blades maintained higher concentrations of photosynthetic pigments compared to sun exposed thalli concurring with established research. Photosynthetic efficiency measurements indicated emersion and not sun exposure was the greater facilitator of photoinhibitory damage and ROS generation at PSII. The findings of this field study strengthen previous assertions that protection via elevated antioxidant metabolism and increased PSII repair are involved in providing relief from the acute environmental stresses in the intertidal zone. (c) 2008 Elsevier B.V. All rights reserved