Climate swings and ecosystem effects by Stig Falk-Petersen, professor, dr. philos Norwegian Polar Institute
The effect of climate variability on marine biological systems, the Calanus complex Arctic Calanus: The most important animals in high latitude seas because they converts low energy sugar to high energy animal fat Why do we have 3 Calanus species in the Arctic? They are all: efficient herbivores high total lipid 50-70%
Diatoms and Calanus The Cenozoic record of diatoms and the appearance of the copepod super families with myelin-sheathed nerve fibres and short lived, none feeding males (Calanus) appeared 65 MYA coincides with Expansion of the polar ice cap, cooling of the ocean, increased wind, thermohaline circulation, turbulent mixing, seasonality of production i.e. Strongly pulsed primary production
The Norwegian Atlantic Currents natural variability over the last 3000 years (from Nalan Koc) 1.5 C Little Ice Age Medieval Warm Period Holocene Warm Period I Holocene Cold Period I Holocene Warm Period II To day Little ice edge - 1.5 o C colder in 10-years
Latitude Record northerly (82 N) location of the ice edge in autumn 2004, not observed since 1751 83 82 2004 * 81 80 79 78 77 76 75 74 1580 1600 1620 1640 1660 1680 1700 1720 1740 1760 1780 1800 Year 1820 1840 1860 1880 1900 1920 1940 1960 1980 2000 Vinje 1999, Falk-Petersen et al. 2007
Environmental variability (ice cover) exists on all time scales: days, decades, centennial and geological scales Effect on: Light The total primary production The timing of the Arctic bloom Geographical area of the production The pulsed Arctic bloom is important for : Accumulating large lipid reserves Lifecycles strategy Development biology
The concept of Arctic plankton blooms (blooms occurs at the retreating ice edge and in leads as the ice melts) Falk-Petersen et al 2007
The Arctic Calanus The genus Calanus is engineered to: 1) feed on pulses of energy 2) convert low energy sugars to a high energy lipids 3) store energy in strongly pulsed systems (This is further support by the development of specialized biosynthetic pathways for wax ester formation) but Why three species? The Arctic climate variability has created three ecological niches for herbivores
Life cycle strategy 1. Life span
2. Growth of the different copepodite stages
The current system in the Arctic. 3. Core over wintering areas for C. finmarchicus, C. glacialis and C. hyperboreus
The three species are adapted to the timing of the bloom Calanus finmarchicus is a deep-water species adapted to a regular yearly spring bloom => the Norwegian Sea. Calanus glacialis is a shelf species adapted to large variations in the timing and length of the annual bloom => northern Barents Sea, Siberian and American shelves. Calanus hyperboreus is a deepwater species adapted to large inter-annual variations in ice cover and algal blooms => central Arctic Ocean, Greenland Sea and Fram Strait.
The Arctic Calanus herbivores has adapted to climate variability in the Arctic: as genus by accumulate energy reserves (lipids). The Arctic Calanus species are herbivores designed to feed on the Arctic diatom blooms as species / populations by developing different life strategy. Timing of the bloom determines the life strategy of the individual species and biodiversity of the Calanus complex
We hypotheses that: the European Arctic ecosystem will switch between a C. finmarchicus and a C.glacialis / C.hyperboreus system dependent on the climate mode Energy level and size spectrum of Calanus as prey C. hyperboreus is 2 times larger than C. finmarchicus Calanus hyperboreus has 26 and C. glacialis 10 times as much energy as C. finmarchicus, per individual
Climate swings and ecosystem effects on Little Auk The sampling sites and the location of the little auk colony Steen et al. 2007
Abundance of the three species Calanus hyperboreus, C. glacialis and C. finmarchicus at the four stations in Isfjorden. AF CV CIV CIII CII CI D1 AF CV CIV CIII CII CI. D3 AF CV CIV CIII CII CI 0 100 200 300 400 Ind. m -3 D5 AF CV CIV CIII CII CI 0 50 100 150 200 Ind. m -3 D7 C. finmarchicus C. glacialis C. hyperboreus Steen et al. 2007, 27th of July 2005 0 40 80 120 Ind. m -3 0 40 80 120 160 Ind. m -3
Frequency of occurrence of prey species in gular pouch Two diets groups: on containing less than 25% C. hyperboreus (19) and those containing more (5). Bold, prey items that occur in 10% or more Diets with less than 25% C. hyperboreus Diets with less than 25% C. hyperboreus Species Mean SE Mean SE Calanus finmarchicus CV 0.051 0.018 0.004 0.004 Calanus glacialis CIV 0.006 0.002 0.007 0.007 Calanus glacialis CV 0.571 0.056 0.144 0.019 Calanus glacialis female 0.018 0.002 0.008 0.004 Calanus hyperboreus CIV 0.003 0.002 0.018 0.008 Calanus hyperboreus CV 0.014 0.008 0.407 0.035 Calanus hyperboreus female 0.007 0.003 0.286 0.052 Themisto abyssorum 0.176 0.048 0.029 0.021
Number Minutes away(trip time) Minutter id 36517 bjørndalen Minutter 1200 1000 800 600 An example of trips of 1 bird. Hatch d 11 July 400 200 0 23.7. 25.7. 27.7. 29.7. 31.7. 2.8. 4.8. 6.8. Date 50 45 40 35 30 25 20 15 10 5 0 36517 35ef1 36a3 569a 10-30 60 120 180 240 300 360 420 480 >480 Minutes Duration of foraging trips, 4 birds Steen et al. 2007
Number of gular pouches with Ratio of long to short trips 1: 5.2 5 of 24 contained large C. hyperboreus During the long trips (12 hrs) they can reach the shelf By chance? C.hyp CIV-CVI % 14 12 10 C.hyp CIV-CVI % 8 6 4 Calanus hyperboreus in the gular pouch 2 0 0 5 10 20 30 40 50 60 70 80 100 Percen C hyp in diet
Conclusion We show for the first time bimodal foraging trip for an alcid species Food for chicks close to colony Lack of suitable prey items close to colony to meet energy needs for the parents Flexible foraging strategy evolved to a highly variable environment
The Arctic food chain depends on Calanus species at the base Falk-Petersen et al. 2007
Arts and Arts science and on science Severnyj Poljus
Long term Arctic zooplankton studies Table 1. Contributing institutions and the number and status of available data. Number of samples available exceeds the number of stations as several stations are sampled with a depth resolution. Contact persons at the different institutions are also given. Institutions Number of stations Status Format Supporting data Contact person NPI 451 Analysed Database Temperature, Salinity UNIS 65 Analysed Database with NP Temperature, Salinity APN 16 Partly analysed Excel Temperature, Salinity NCFS/Shirshov 109 Analysed Excel Temperature, Salinity, pigments, carbon MMBI 278 Analysed Unknown spreadsheet PINRO 1486 250 analysed to species, stage, abundance Excel Temperature, Salinity Temperature, Salinity S. Falk- Petersen K. Eiane G. Pedersen M. Reigstad Need new contact after S. Timofeev Emma Orlova
The seasonal distribution of sampling in the different regions.
Distribution of stations covered by PINRO, from 2002. 82 2002 80 78 76 74 72 70 68 10 20 30 40 50 60 70
The SINMOD model Coupled physical biological model. Nested into the 20 km model is the large 4 km grid area (black rectangle) which in turn provides boundary conditions for the main 4 km/800 m model (grey rectangle).
Zooplankton communities, food web structures and sympagic-pelagic coupling in % the ABUNDANCE Svalbard-Barents Sea Marginal Ice Zone Calanus spp. Primarily herbivore (Conover et al. 1991, Scott et al. 2000) Arctic deep water Key link between primary producers and higher trophic levels Experience strong seasonality in food supply Arctic shelf water Overwinter at depth, hibernating (diapause), utilising lipid reserves from previous summer North Atlantic
BIOMASS 32 g C. finmarchicus (0.3 8.7 g DW m -2 ) C. glacialis (0.1 30.6 g DW m -2 ) C. hyperboreus (0.1 2.6 g DW m -2 ) 28 g 0.5 g 10 g Paper V
The Ice Edge Programme The Statoil Ice edge programme Ecological and ecotoxicological studies of ice amphipods Microbial degradation of carbon Arctic primary production Ecology of the key fish species Leptoclinus maculates Effect of oil on Arctic Calanus and Ice Amphipods CLEOPATRA Climate effects on planktonic food quality and trophic transfer in Arctic Marginal Ice Zones The effect of PAR and UV on the quality of the phytoplankton Timing of seasonal migration and spawning of C. glacialis
Increase in size of Calanus versus lipid sac volume (increas in prosome of.5 mm increases the oil volume 2.8 times Daniel Vogedes