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Springer, Karin; Lütz, Cornelius; Lütz-Meindl, Ursula; Wendt, Angela; Bischof, Kai (2018): Hyposaline conditions affect UV susceptibility in the Arctic kelp Alaria esculenta (Phaeophyceae) - results of laboratory experiments at Kongsfjorden, June/July 2014 [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.894853, Supplement to: Springer, K et al. (2017): Hyposaline conditions affect UV susceptibility in the Arctic kelp Alaria esculenta (Phaeophyceae). Phycologia, 56(6), 675-685, https://doi.org/10.2216/16-122.1

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Abstract:
The kelp Alaria esculenta represents a key species in high Arctic marine fjord ecosystems. However, the European Arctic is currently experiencing extensive environmental change. Glacial fjord systems, such as Kongsfjorden (Spitsbergen, Svalbard), are subjected to rising temperature, increased freshwater inflow from glaciers and melting snow and a changing ultraviolet (UV) radiation regime related to stratospheric ozone depletion. Thus, in addition to natural seasonality, sessile organisms require acclimation in order to adapt to an environment in transition. We examined the physiological and ultrastructural responses of A. esculenta to the combined exposure to hyposalinity and UV radiation. Photosynthetic quantum yield slightly decreased during a low-salinity treatment of 7 d. Exposure to UV radiation also lowered quantum yield, but specimens previously treated with hyposalinity were significantly less susceptible to UV than nontreated individuals. Concomitant with a loss of chlorophyll during the hyposaline treatment, phlorotannin and antioxidant contents were maintained, and samples treated with low salinities exhibited higher UV-screening characteristics as demonstrated by significantly higher absorption ratios at 300/680 nm. Ultrastructural analyses revealed a treatment-dependent swelling of cell walls and accumulations of phlorotannin-containing vesicles. Our findings point to a strategy by which kelps apply a fast and cost-efficient redistribution of phlorotannins rather than increased synthesis as a general stress response to different environmental drivers in contrast to stress-specific responses. The notion that acclimation to one stressor (low salinity) reflects increased tolerance towards a second stressor (UV radiation) supports the concept of 'cross-acclimation' as established for higher plants but not yet for seaweeds.
Coverage:
Latitude: 78.916670 * Longitude: 11.933330
Event(s):
KongsfjordenOA * Latitude: 78.916670 * Longitude: 11.933330 * Method/Device: Experiment (EXP)
Comment:
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Treatment details:
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Initial [ini] => SA 32, 0-4°C, <20 µmol photons m-2 s-1 PAR
Salinity I, hyposaline conditions (long-term stress treatment) [sal_I] => SA 15, 4°C, 50 µmol photons m-2 s-1 PAR for 7 days
Salinity II, extreme hyposaline conditions (short-term stress treatment) [sal_II] => SA 5, 4°C, 50 µmol photons m-2 s-1 PAR for 6 hours
Ultraviolett radiation I (long-term stress treatment) [UV_I] => SA 32, 4°C, 6.8 W m-2 UVA [320-400 nm] and 0.5 W m-2 UVB [280-320 nm] for 7 days
Ultraviolett radiation II (short-term stress treatment) [UV_II] => SA 32, 4°C, 7.5 W m-2 UVA [320-400 nm] and 0.8 W m-2 UVB [280-320 nm] for 6 hours
Control conditions [control] => SA 32, 4°C, 50 µmol photons m-2 s-1 PAR
Recovery conditions (intermediate and final recovery period) [rec. (sal_I), rec. (UV_I), rec. control (sal_II), rec. control (UV_II) ] => SA 32, 4°C, 50 µmol photons m-2 s-1 PAR
Parameter(s):
#NameShort NameUnitPrincipal InvestigatorMethod/DeviceComment
SpeciesSpeciesSpringer, Karin
FamilyFamilySpringer, Karin
TreatmentTreatSpringer, Karin
Maximum photochemical quantum yield of photosystem IIFv/FmSpringer, Karin
Maximal electron transport rateETR maxµmol/m2/sSpringer, Karin
Initial slope of rapid light curvealphaµmol electrons/µmol quantaSpringer, Karin
Light saturation pointIkµmol/m2/sSpringer, Karin
Chlorophyll aChl aµg/gSpringer, Karinwet mass
Chlorophyll c1+c2Chl c1+c2µg/gSpringer, Karinwet mass
10 FucoxanthinFucoµg/gSpringer, Karinwet mass
11 beta-Caroteneb-Carµg/gSpringer, Karinwet mass
12 Violaxanthin + Antheraxanthin + ZeaxanthinViola+Anth+Zeaµg/gSpringer, Karinwet mass
13 PhlorotanninsPhloromg/gSpringer, Karindry mass
14 Antioxidant capacity, in Trolox EquivalentsTEACmg/gSpringer, Karindry mass
15 RatioRatioSpringer, KarinPhlorotannins per Chl a
16 RatioRatioSpringer, KarinAntioxidants per Chl a
License:
Creative Commons Attribution 4.0 International (CC-BY-4.0)
Size:
96 data points

Data

Download dataset as tab-delimited text — use the following character encoding:


Species
Family
Treat
Fv/Fm
ETR max [µmol/m2/s]
alpha [µmol electrons/µmol quanta]
Ik [µmol/m2/s]
Chl a [µg/g]
(wet mass)
Chl c1+c2 [µg/g]
(wet mass)		10 
Fuco [µg/g]
(wet mass)		11 
b-Car [µg/g]
(wet mass)		12 
Viola+Anth+Zea [µg/g]
(wet mass)		13 
Phloro [mg/g]
(dry mass)		14 
TEAC [mg/g]
(dry mass)		15 
Ratio
(Phlorotannins per Chl a)		16 
Ratio
(Antioxidants per Chl a)
Alaria esculentaPhaeophyceaeinitial0.59434.2730.204170.942685.725989.7419218.656322.585342.136233.35082.67250.0000106980.8608
Alaria esculentaPhaeophyceaesal_I0.54634.8750.200178.121412.135750.7736178.097812.380620.905030.91292.63570.0000106981.5201
Alaria esculentaPhaeophyceaeUV_I0.50226.8780.136218.288611.683473.6728208.847516.785132.595330.52052.80690.0000107690.9968
Alaria esculentaPhaeophyceaecontrol0.59035.7180.183196.824608.509169.9252203.763616.712830.672929.86892.79350.0000127741.1854
Alaria esculentaPhaeophyceaecrossing sal_I -> UV_II0.468
Alaria esculentaPhaeophyceaerecovery sal_!0.495
Alaria esculentaPhaeophyceaecontrol UV_II0.237
Alaria esculentaPhaeophyceaerecovery control UV_II0.588
Alaria esculentaPhaeophyceaecrossing UV_I -> sal_II0.619
Alaria esculentaPhaeophyceaerecovery UV_I0.450
Alaria esculentaPhaeophyceaecontrol sal_II0.431
Alaria esculentaPhaeophyceaerecovery control sal_II0.500