INTERACTIONS BETWEEN UV RADIATION AND TEMPERATURE LIMIT INFERENCES FROM SINGLE‐FACTOR EXPERIMENTS<sup>1</sup>

Hoffman, Jennifer R.; Hansen, Lara J.; Klinger, Terrie

doi:10.1046/j.1529-8817.2003.01111.x

Cited by 83 publications

(90 citation statements)

References 22 publications

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“…A coupled effect of UVR and temperature on phytoplankton growth has been found in cyanobacteria (Roos and Vincent 1998) and in early life stages of intertidal algae (Hoffman et al 2003). While Lotze and Worm (2002) found synergistic effects of nutrient enrichment, grazing, temperature, and UVR exposure on a green macroalga, the complex interaction observed here among UVR, temperature, and nutrients has not been previously documented in phytoplankton.…”

Section: Discussionmentioning

confidence: 59%

Interactive effects of temperature and nutrient limitation on the response of alpine phytoplankton growth to ultraviolet radiation

2005

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We performed bag-enclosure experiments for 7 d in a lake in the Beartooth Mountains (in Montana and Wyoming) using natural phytoplankton assemblages. Ultraviolet radiation (UVR) (exposed or blocked), temperature (6ЊC and 14ЊC), and nutrients (nitrogen, phosphorus, and nitrogen plus phosphorus) were manipulated in a factorial design to determine how these factors interact to affect phytoplankton growth. Four major phytoplankton taxa (two diatoms, one chrysophyte, and one dinoflagellate) were found in the water samples across all treatments. Greater growth rates were observed at the higher temperature for all taxa, except the chrysophyte. UVR depressed the growth rates of all phytoplankton at 6ЊC regardless of nutrient conditions. In contrast, at 14ЊC, a negative effect of UVR was not observed for any species in the absence of nutrient additions; only with the addition of nutrients did UVR exposure depress the growth of one diatom species and the dinoflagellate. Our results suggest that in alpine lakes, the effects of UVR exposure on phytoplankton depend on temperature and nutrient availability, indicating that climate change and enhanced atmospheric nitrogen deposition are likely to alter UV-temperature-nutrient relationships of plankton in high-UV systems.

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Section: Discussionmentioning

confidence: 59%

Interactive effects of temperature and nutrient limitation on the response of alpine phytoplankton growth to ultraviolet radiation

2005

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“…from both locations (Table 2). Likewise higher detrimental UV-B effects at lower temperatures were observed in studies with unicellular propagules and sporophytes of red, brown and green algae, regarding recruitment, photosynthetic performance and DNA damage , Gómez et al 2001, Altamirano et al 2003, Hoffmann et al 2003, Rautenberger & Bischof 2006. Whilst UV-Binduced DNA damage appears to be independent of temperature, enzymatic DNA repair is more effective at higher temperatures .…”

Section: Reproductive Success Of Laminariales Under Changing Temperatmentioning

confidence: 92%

Interactive effects of UV radiation and temperature on microstages of Laminariales (Phaeophyceae) from the Arctic and North Sea

Müller

Wiencke²,

Bischof³

2008

Clim. Res.

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Spores and gametophytes are considered to be those life-history stages of kelps most susceptible to environmental perturbations and, in particular, to temperature and UV radiation. Microstages of Arctic (Saccharina latissima, Laminaria digitata, Alaria esculenta from Spitsbergen) and temperate kelp species (S. latissima, L. digitata, L. hyperborea from the North Sea) were exposed in 2-factorial experiments to different temperatures (2 to 18°C) and radiation conditions (photosynthetic active radiation, UV-A radiation, UV-B radiation). Our results reveal ecotypic differentiations in the stress responses of zoospores of L. digitata and S. latissima from the Arctic and North Sea. UV-A radiation either enhanced the formation of gametes at elevated temperatures in L. digitata or impaired egg release and subsequent sporophyte formation in L. hyperborea. Microstages exposed to additional UV-B radiation were strongly inhibited to a population-, species-and life phase-specific degree at suboptimal and optimal temperatures. Only gametogenesis of Laminaria spp. was shown to be tolerant to UV-B exposure. Conclusively, in respect to a future scenario of elevated UV radiation regimes and higher summer temperatures in Arctic and North Sea waters, summer-recruiting Arctic species and L. digitata from the North Sea might become endangered by a frequent disturbance of their microstages.

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“…[25][26][27][28] There are also reports showing the beneficial effects of increased temperature on the germination rate, cell number, photosynthesis (F v /F m ), and DNA damage repair rates of macroalgae. [29][30][31][32] Zoospore germination in the Arctic population of Alaria esculenta, Laminaria digitata and Saccharina latissima was optimal between 2 and 12 • C, and impaired at 18 • C. 33 Significant additional negative UV-B effect was observed at 2 and 12 • C in L. digitata and at 12 • C in S. latissima, but not in A. esculenta. 33 Whether the temperature optima for photosynthesis are the same or higher than the optimum temperatures for growth (or germination) in different Arctic kelp zoospores is yet to be studied.…”

Section: Introductionmentioning

confidence: 99%

Photosynthetic response of Arctic kelp zoospores exposed to radiation and thermal stress

Roleda

2009

Photochem Photobiol Sci

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Zoospores of Arctic kelp species, Alaria esculenta, Laminaria digitata and Saccharina latissima were exposed to different temperature (2 • C to 19 • C) and radiation (photosynthetically active radiation (PAR = P), PAR + UV-A (PA), and PAR + UV-A + UV-B (PAB)) conditions in the laboratory. Species-specific responses to the combined effect of light and temperature stress showed sensitivity in the order S. latissima > L. digitata > A. esculenta. The optimum temperature range for photosynthesis in different Arctic kelp species' zoospores was between 7-13 • C, temperatures higher than in the natural environment. Short-term response to increasing temperature was non-lethal while moderate temperature increase had an ameliorating effect on the overall biological effect of UVR; where the lowest photoinhibition was observed at 13 • C under PAB and higher photosynthetic recovery was observed in UVR-pre-exposed zoospores at 7-13 • C compared to 2 • C. Above the temperature optima, continued cultivation under high temperature had a negative impact on the recovery of photoinhibition. The higher capacity for non-photochemical quenching (NPQ) in A. esculenta and L. digitata helped to regulate and protect photosynthesis under light and temperature stress compared to S. latissima. The investigated Arctic kelp species may be able to locally survive under the influence of UVR at a certain range of temperature increase but the southernmost distribution range of the species may shift to higher latitudes; although natural selection may result in genotypes adapted to stressful environment.

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INTERACTIONS BETWEEN UV RADIATION AND TEMPERATURE LIMIT INFERENCES FROM SINGLE‐FACTOR EXPERIMENTS¹

Cited by 83 publications

References 22 publications

Interactive effects of temperature and nutrient limitation on the response of alpine phytoplankton growth to ultraviolet radiation

Interactive effects of temperature and nutrient limitation on the response of alpine phytoplankton growth to ultraviolet radiation

Interactive effects of UV radiation and temperature on microstages of Laminariales (Phaeophyceae) from the Arctic and North Sea

Photosynthetic response of Arctic kelp zoospores exposed to radiation and thermal stress

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INTERACTIONS BETWEEN UV RADIATION AND TEMPERATURE LIMIT INFERENCES FROM SINGLE‐FACTOR EXPERIMENTS1

Cited by 83 publications

References 22 publications

Interactive effects of temperature and nutrient limitation on the response of alpine phytoplankton growth to ultraviolet radiation

Interactive effects of temperature and nutrient limitation on the response of alpine phytoplankton growth to ultraviolet radiation

Interactive effects of UV radiation and temperature on microstages of Laminariales (Phaeophyceae) from the Arctic and North Sea

Photosynthetic response of Arctic kelp zoospores exposed to radiation and thermal stress

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INTERACTIONS BETWEEN UV RADIATION AND TEMPERATURE LIMIT INFERENCES FROM SINGLE‐FACTOR EXPERIMENTS¹