Your search keyword '"Albretsen, Jon"' showing total 6 results

1. Climate change opens new frontiers for marine species in the Arctic: Current trends and future invasion risks.

Author

Chan FT, Stanislawczyk K, Sneekes AC, Dvoretsky A, Gollasch S, Minchin D, David M, Jelmert A, Albretsen J, and Bailey SA

Subjects

Animals, Arctic Regions, Biodiversity, Ecosystem, Introduced Species statistics & numerical data, Risk, Aquatic Organisms physiology, Climate Change, Introduced Species trends

Abstract

Climate change and increased anthropogenic activities are expected to elevate the potential of introducing nonindigenous species (NIS) into the Arctic. Yet, the knowledge base needed to identify gaps and priorities for NIS research and management is limited. Here, we reviewed primary introduction events to each ecoregion of the marine Arctic realm to identify temporal and spatial patterns, likely source regions of NIS, and the putative introduction pathways. We included 54 introduction events representing 34 unique NIS. The rate of NIS discovery ranged from zero to four species per year between 1960 and 2015. The Iceland Shelf had the greatest number of introduction events (n = 14), followed by the Barents Sea (n = 11), and the Norwegian Sea (n = 11). Sixteen of the 54 introduction records had no known origins. The majority of those with known source regions were attributed to the Northeast Atlantic and the Northwest Pacific, 19 and 14 records, respectively. Some introduction events were attributed to multiple possible pathways. For these introductions, vessels transferred the greatest number of aquatic NIS (39%) to the Arctic, followed by natural spread (30%) and aquaculture activities (25%). Similar trends were found for introductions attributed to a single pathway. The phyla Arthropoda and Ochrophyta had the highest number of recorded introduction events, with 19 and 12 records, respectively. Recommendations including vector management, horizon scanning, early detection, rapid response, and a pan-Arctic biodiversity inventory are considered in this paper. Our study provides a comprehensive record of primary introductions of NIS for marine environments in the circumpolar Arctic and identifies knowledge gaps and opportunities for NIS research and management. Ecosystems worldwide will face dramatic changes in the coming decades due to global change. Our findings contribute to the knowledge base needed to address two aspects of global change-invasive species and climate change., (© 2018 The Authors. Global Change Biology Published by John Wiley & Sons Ltd.)

Published

2019

2. Climate Change and Genetic Structure of Leading Edge and Rear End Populations in a Northwards Shifting Marine Fish Species, the Corkwing Wrasse (Symphodus melops).

Author

Knutsen H, Jorde PE, Gonzalez EB, Robalo J, Albretsen J, and Almada V

Subjects

Animals, DNA, Mitochondrial genetics, North Sea, Climate Change, Fishes genetics, Gene Flow, Genetic Variation, Genetics, Population, Microsatellite Repeats

Abstract

One mechanism by which marine organisms may respond to climate shifts is range shifts. The corkwing wrasse (Symphodus melops) is a temperate fish species, inhabiting the coasts of Europe, that show strong indications of current as well as historical (ice-age) range shifts towards the north. Nine neutral microsatellite DNA markers were screened to study genetic signatures and spatial population structure over the entire geographic and thermal gradient of the species from Portugal to Norway. A major genetic break (F ST  = 0.159 average among pairs) was identified between Scandinavian and more southern populations, with a marked reduction (30% or more) in levels of genetic variability in Scandinavia. The break is probably related to bottleneck(s) associated with post-glacial colonization of the Scandinavian coasts, and indicates a lack of present gene flow across the North Sea. The lack of gene flow can most likely be attributed to the species' need for rocky substrate for nesting and a relatively short pelagic larval phase, limiting dispersal by ocean currents. These findings demonstrate that long-distance dispersal may be severely limited in the corkwing wrasse, and that successful range-shifts following present climate change may be problematic for this and other species with limited dispersal abilities, even in the seemingly continuous marine environment.

Published

2013

3. Environmental change influences the life history of salmon Salmo salar in the North Atlantic Ocean

Author

Jonsson, Bror, Jonsson, Nina, and Albretsen, Jon

Subjects

Time series, Klimaendringer, VDP::Marine biology: 497, VDP::Marinbiologi: 497, Marinbiologi: 497 [VDP], Temperatur, Temperature, Climate change, Growth, Marine biology: 497 [VDP], Vekst, Tidsrekker

Abstract

Annual mean total length (LT) of wild one-sea-winter (1SW) Atlantic salmon Salmo salar of the Norwegian River Imsa decreased from 63 to 54 cm with a corresponding decrease in condition factor (K) for cohorts migrating to sea from 1976 to 2010. The reduction in LT is associated with a 40% decline in mean individual mass, from 2 to 1⋅2 kg. Hatchery fish reared from parental fish of the same population exhibited similar changes from 1981 onwards. The decrease in LT correlated negatively with near-surface temperatures in the eastern Norwegian Sea, thought to be the main feeding area of the present stock. Furthermore, S. salar exhibited significant variations in the proportion of cohorts attaining maturity after only one winter in the ocean. The proportion of S. salar spawning as 1SW fish was lower both in the 1970s and after 2000 than in the 1980s and 1990s associated with a gradual decline in post-smolt growth and smaller amounts of reserve energy in the fish. In wild S. salar, there was a positive association between post-smolt growth and the sea survival back to the River Imsa for spawning. In addition, among smolt year-classes, there were significant positive correlations between wild and hatchery S. salar in LT, K and age at maturity. The present changes may be caused by ecosystem changes following the collapse and rebuilding of the pelagic fish abundance in the North Atlantic Ocean, a gradual decrease in zooplankton abundance and climate change with increasing surface temperature in the Norwegian Sea. Thus, the observed variation in the life-history traits of S. salar appears primarily associated with major changes in the pelagic food web in the ocean. climate change; condition factor; growth; sea survival; temperature; time series. © 2016 The Fisheries Society of the British Isles

Published

2016

4. Utredning av program for overvåking av klimaendringseffekter i norske kyst- og havområder

Author

Mork, Kjell Arne, Naustvoll, Lars-Johan, Albretsen, Jon, and Ingvaldsen, Randi

Subjects

monitoring, climate change, klimaendringer, VDP::Mathematics and natural science: 400::Geosciences: 450::Oceanography: 452, overvåkning

Abstract

Existing monitoring programmes have, in several cases, often started from projects with focus on process studies and also as a short-term activity. Thus, the present monitoring programmes are often limited in terms of distinguishing between the effects of natural climate variability from the human influenced change. The present report makes an attempt to draft a national programme for the monitoring of the environment where the effects of the climate change have been accounted for. The suggested monitoring programme is built over national monitoring programmes (e.g., EUs Framework Directive for Water and integrated management plans for Norwegian waters) and other ongoing monitoring programmes that include long-term data series. The proposed programme is divided into three geographical areas; Coastal, Ocean and Arctic with annual budgets for the extended monitoring of 4, 3.5 and 4 mill NOK, respectively.

Published

2012

5. Climate Change and Genetic Structure of Leading Edge and Rear End Populations in a Northwards Shifting Marine Fish Species, the Corkwing Wrasse (Symphodus melops).

Author

Knutsen, Halvor, Jorde, Per Erik, Gonzalez, Enrique Blanco, Robalo, Joana, Albretsen, Jon, and Almada, Vitor

Subjects

CLIMATE change, MARINE organisms, MICROSATELLITE repeats, GENETIC markers, BIOLOGICAL variation, MARINE fishes, WRASSES

Abstract

One mechanism by which marine organisms may respond to climate shifts is range shifts. The corkwing wrasse (Symphodus melops) is a temperate fish species, inhabiting the coasts of Europe, that show strong indications of current as well as historical (ice-age) range shifts towards the north. Nine neutral microsatellite DNA markers were screened to study genetic signatures and spatial population structure over the entire geographic and thermal gradient of the species from Portugal to Norway. A major genetic break (FST  = 0.159 average among pairs) was identified between Scandinavian and more southern populations, with a marked reduction (30% or more) in levels of genetic variability in Scandinavia. The break is probably related to bottleneck(s) associated with post-glacial colonization of the Scandinavian coasts, and indicates a lack of present gene flow across the North Sea. The lack of gene flow can most likely be attributed to the species’ need for rocky substrate for nesting and a relatively short pelagic larval phase, limiting dispersal by ocean currents. These findings demonstrate that long-distance dispersal may be severely limited in the corkwing wrasse, and that successful range-shifts following present climate change may be problematic for this and other species with limited dispersal abilities, even in the seemingly continuous marine environment. [ABSTRACT FROM AUTHOR]

Published

2013

6. Climate Change and Genetic Structure of Leading Edge and Rear End Populations in a Northwards Shifting Marine Fish Species, the Corkwing Wrasse (Symphodus melops).

Author

Knutsen, Halvor, Jorde, Per Erik, Gonzalez, Enrique Blanco, Robalo, Joana, Albretsen, Jon, and Almada, Vitor

Subjects

*CLIMATE change, *MARINE organisms, *MICROSATELLITE repeats, *GENETIC markers, *BIOLOGICAL variation, *MARINE fishes, *WRASSES

Abstract

One mechanism by which marine organisms may respond to climate shifts is range shifts. The corkwing wrasse (Symphodus melops) is a temperate fish species, inhabiting the coasts of Europe, that show strong indications of current as well as historical (ice-age) range shifts towards the north. Nine neutral microsatellite DNA markers were screened to study genetic signatures and spatial population structure over the entire geographic and thermal gradient of the species from Portugal to Norway. A major genetic break (FST  = 0.159 average among pairs) was identified between Scandinavian and more southern populations, with a marked reduction (30% or more) in levels of genetic variability in Scandinavia. The break is probably related to bottleneck(s) associated with post-glacial colonization of the Scandinavian coasts, and indicates a lack of present gene flow across the North Sea. The lack of gene flow can most likely be attributed to the species’ need for rocky substrate for nesting and a relatively short pelagic larval phase, limiting dispersal by ocean currents. These findings demonstrate that long-distance dispersal may be severely limited in the corkwing wrasse, and that successful range-shifts following present climate change may be problematic for this and other species with limited dispersal abilities, even in the seemingly continuous marine environment. [ABSTRACT FROM AUTHOR]

Published

2013