Your search keyword '"Langangen Ø"' showing total 48 results

1. Attraction of cod Gadus morhua from coastal spawning grounds to salmon farms

Author

Skjæraasen, J. E., Karlsen, Ø., Langangen, Ø., Meier, S., Dunlop, K. M., van der Meeren, T., Keeley, N. B., Myksvoll, M. S., Dahle, G., Moland, E., Nilsen, R., Schrøder, K. M. Elvik, Bannister, R. J., and Olsen, E. M.

Published

2022

2. How the spatio-temporal overlap of cod, haddock, and capelin larvae affects their recruitment in the Norwegian-Barents Sea system

Author

Ferreira, ASA, primary, Langangen, Ø, additional, Yaragina, NA, additional, Prokopchuk, IP, additional, and Durant, JM, additional

Published

2024

3. Interference of Light in Michelson-Morley Interferometer: A Quantum Optical Approach

Author

Langangen, O., Skagerstam, B. -S., and Vaskinn, A.

Subjects

Quantum Physics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

We investigate how the temporal coherence interference properties of light in a Michelson-Morley interferometer (MMI), using only a single-photon detector, can be understood in a quantum-optics framework in a straightforward and pedagogical manner. For this purpose we make use of elementary quantum field theory and Glaubers theory for photon detection in order to calculate the expected interference pattern in the MMI. If a thermal reference source is used in the MMI local oscillator port in combination with a thermal source in the signal port, the interference pattern revealed by such an intensity measurement shows a distinctive dependence on the differences in the temperature of the two sources. The MMI can therefore be used in order to perform temperature measurements. A related method was actually used to carry out high precision measurements of the cosmic micro-wave background radiation on board of the COBE satellite. The theoretical framework allows us to consider any initial quantum state. The interference of single photons as a tool to determine the angular peak-frequency of a one-photon pulse interfering with a single-photon reference pulse is, e.g., considered. A similar consideration for coherent laser pulses leads to a different response in the detector. The MMI experimental setup is therefore in a sense an example of an optical device where one can exhibit the difference between classical and quantum-mechanical light using only intensity measurements., Comment: 9 pages, 5 figures, added references and corrected for typographical errors

Published

2011

4. Swaying threads of a solar filament

Author

Lin, Y., Soler, R., Engvold, O., Ballester, J. L., Langangen, Ø., Oliver, R., and van der Voort, L. H. M. Rouppe

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

From recent high resolution observations obtained with the Swedish 1 m Solar Telescope in La Palma, we detect swaying motions of individual filament threads in the plane of the sky. The oscillatory character of these motions are comparable with oscillatory Doppler signals obtained from corresponding filament threads. Simultaneous recordings of motions in the line of sight and in the plane of the sky give information about the orientation of the oscillatory plane. These oscillations are interpreted in the context of the magnetohydrodynamic theory. Kink magnetohydrodynamic waves supported by the thread body are proposed as an explanation of the observed thread oscillations. On the basis of this interpretation and by means of seismological arguments, we give an estimation of the thread Alfv\'en speed and magnetic field strength by means of seismological arguments., Comment: Accepted for publication in the Astrophysical Journal

Published

2009

5. Velocity dispersions in a cluster of stars: How fast could Usain Bolt have run?

Author

Eriksen, H. K., Kristiansen, J. R., Langangen, O., and Wehus, I. K.

Subjects

Physics - Popular Physics, Astrophysics

Abstract

Since that very memorable day at the Beijing 2008 Olympics, a big question on every sports commentator's mind has been "What would the 100 meter dash world record have been, had Usain Bolt not celebrated at the end of his race?" Glen Mills, Bolt's coach suggested at a recent press conference that the time could have been 9.52 seconds or better. We revisit this question by measuring Bolt's position as a function of time using footage of the run, and then extrapolate into the last two seconds based on two different assumptions. First, we conservatively assume that Bolt could have maintained Richard Thompson's, the runner-up, acceleration during the end of the race. Second, based on the race development prior to the celebration, we assume that he could also have kept an acceleration of 0.5 m/s^2 higher than Thompson. In these two cases, we find that the new world record would have been 9.61 +/- 0.04 and 9.55 +/- 0.04 seconds, respectively, where the uncertainties denote 95% statistical errors., Comment: 5 pages, 4 figures, submitted American Journal of Physics; high-resolution NBC footage allowed better measurements between 6 and 8 seconds compared to version 1

Published

2008

6. Search for high velocities in the disk counterpart of type II spicules

Author

Langangen, Ø., De Pontieu, B., Carlsson, M., Hansteen, V. H., Cauzzi, G., and Reardon, K.

Subjects

Astrophysics

Abstract

Recently, De Pontieu et al. (2007b) discovered a class of spicules that evolves more rapidly than previously known spicules, with rapid apparent motions of 50--150 km s${}^{-1}$, thickness of a few 100 km, and lifetimes of order 10--60 seconds. These so-called type II spicules have been difficult to study because of limited spatio-temporal and thermal resolution. Here we use the IBIS instrument to search for the high velocities in the disk counterpart of type II spicules. We have detected rapidly evolving events, with lifetimes that are less than a minute and often equal to the cadence of the instrument (19 secs). These events are characterized by a Doppler shift that only appears in the blue wing of the Ca II IR line. Furthermore the spatial extent, lifetime, and location near network, all suggest a link to type II spicules. However, the magnitude of the measured Doppler velocity is significantly lower than the apparent motions seen at the limb. We use Monte Carlo simulations to show that this discrepancy can be explained by a forward model in which the visibility on the disk of the high-velocity flows in these events is limited by a combination of line-of-sight projection and reduced opacity in upward propelled plasma, especially in reconnection driven jets that are powered by a roughly constant energy supply., Comment: 4 pages, Accepted in ApJL

Published

2008

7. Exploring drift simulations from ocean circulation experiments: application to cod eggs and larval drift

Author

Melsom, A, primary, KØ, Kvile, additional, Dagestad, KF, additional, Broström, G, additional, and Langangen, Ø, additional

Published

2022

8. Low impact of first-time spawners on population growth in a brown trout population

Author

Stubberud, MW, primary, Nater, CR, additional, Vindenes, Y, additional, Vøllestad, LA, additional, and Langangen, Ø, additional

Published

2022

9. Stock collapse and its effect on species interactions: cod and herring in the Norwegian-Barents Seas system as an example

Author

Durant J, Aarvold L, and Langangen Ø

Subjects

Fishery, Herring, language, Collapse (topology), Norwegian, Geology, Stock (geology), language.human_language

Abstract

Both the Norwegian Spring Spawning herring (Clupea harengus) and the Northeast Arctic cod (Gadus morhua) are examples of how the overexploitation of marine fish populations was leading to a strong reduction even so stock collapse, with a strong decline in the associated fisheries, followed by a recovery. Cod and herring are both part of the Barents Sea ecosystem, which experienced major warming events in the early (1920-1940) and late 20th century. While the collapse or near collapse of these stocks seems to be linked to instability created by overfishing and climate, the difference of population dynamics before and after is not fully understood. In particular, it is unclear how the changes in population dynamics before and after the collapses are associated with biotic interactions. The combination of the availability of unique long-term time series for herring and cod makes it a well-suited study system to investigate the effects of collapse. We examine how species interactions may differently affect the herring and cod population dynamic before and after a collapse. Particularly we explore, using a GAM modelling approach, how herring could affect cod and reciprocally. We found that the effect on herring of cod biomass that was generally positive (i.e., covariation) became negative after the collapse (i.e., predation or competition). Likewise a change occurred for the cod, the juvenile herring biomass that had no effect before the collapse had a negative one after. Our results indicate that population collapses may lead to altered inter-specific interactions as well as altered response to abiotic environmental variations. While the stocks are at similar abundance levels before and after the collapses the system is potentially different in its functioning and may require different management action.

Published

2021

10. Effects of sea ice cover, temperature and predation on the stock dynamics of the key Arctic fish species polar cod Boreogadus saida

Author

Dupont, N, primary, Durant, JM, additional, Gjøsæter, H, additional, Langangen, Ø, additional, and Stige, LC, additional

Published

2021

11. Impact of salmon farming on Atlantic cod spatio-temporal reproductive dynamics

Author

Skjæraasen, JE, primary, Karlsen, Ø, additional, Langangen, Ø, additional, van der Meeren, T, additional, Keeley, NB, additional, Myksvoll, MS, additional, Dahle, G, additional, Moland, E, additional, Nilsen, R, additional, Elvik Schrøder, KM, additional, Bannister, RJ, additional, and Olsen, EM, additional

Published

2021

12. Towards a future without stocking: harvest and river regulation determine long-term population viability of migratory salmonids

Author

Nater, CR, primary, Stubberud, MW, additional, Langangen, Ø, additional, Rustadbakken, A, additional, Moe, SJ, additional, Ergon, T, additional, Vøllestad, LA, additional, and Vindenes, Y, additional

Published

2021

13. Increased early offspring growth can offset the costs of long-distance spawning migration in fish

Author

Färber, L, primary, Durant, JM, additional, Vindenes, Y, additional, and Langangen, Ø, additional

Published

2018

14. The effects of oil spills on marine fish: Implications of spatial variation in natural mortality

Author

Langangen, Ø., primary, Olsen, E., additional, Stige, L.C., additional, Ohlberger, J., additional, Yaragina, N.A., additional, Vikebø, F.B., additional, Bogstad, B., additional, Stenseth, N.C., additional, and Hjermann, D.Ø., additional

Published

2017

15. Timecourse of oocyte development in saithePollachius virens

Author

Skjaeraasen, J. E., primary, Devine, J. A., additional, Godiksen, J. A., additional, Fonn, M., additional, OtterÅ, H., additional, Kjesbu, O. S., additional, Norberg, B., additional, Langangen, Ø., additional, and Karlsen, Ø., additional

Published

2016

16. Interference of Light in a Michelson-Morley Interferometer: A Quantum Optical Approach

Author

Langangen, Ø., Vaskinn, A., and Skagerstam, B.-S.

Subjects

Article Subject

Abstract

The temporal coherence interference properties of light as revealed by single detector intensity measurements in a Michelson-Morley interferometer (MMI) is often described in terms of classical optics. We show, in a pedagogical manner, how such features of light also can be understood in terms of a more general quantum-optics framework. If a thermal reference source is used in the MMI local oscillator port in combination with a thermal source in the signal port, the interference pattern revealed by single detector intensity measurements shows a distinctive dependence on the differences in the temperature of the two sources. A related method has actually been used to perform high-precision measurements of the cosmic microwave background radiation. The general quantum-optics framework allows us to consider any initial quantum state. As an example, we consider the interference of single photons as a tool to determine the peak angular-frequency of a single-photon pulse interfering with a single-photon reference pulse. A similar consideration for laser pulses, in terms of coherent states, leads to a different response in the detector. The MMI experimental setup is therefore an example of an optical device where one, in terms of intensity measurements, can exhibit the difference between classical and quantum-mechanical light.

Published

2012

17. Timecourse of oocyte development in saithe Pollachius virens.

Author

Skjæraasen, J. E., Devine, J. A., Godiksen, J. A., Fonn, M., OtterÅ, H., Kjesbu, O. S., Norberg, B., Langangen, Ø., and Karlsen, Ø.

Subjects

POLLOCK, FISH fertility, SEX hormones, FISH growth, SIZE of fishes, FISH spawning

Abstract

Wild caught North Sea saithe Pollachius virens were monitored for growth, sex steroid profiles and oocyte development pre-spawning and measured for egg size and group fecundity during the spawning season in the laboratory. Vitellogenesis commenced in late October-early November, at a leading cohort size ( CL) of c. 250 µm, after which oocytes grew rapidly in size until spawning started in February. Notably, a distinct cortical alveoli stage was virtually absent with yolk granules observed in developing oocytes at the very beginning of vitellogenesis. Little atresia was observed pre-spawning, but atretic re-absorption of remnant oocytes containing yolk granules was found in all females immediately post-spawning. As expected, concentrations of sex steroids, oestradiol-17β (females), testosterone (both sexes) and 11-ketotestosterone (both sexes), increased pre-spawning before dropping post-spawning. The present experiment provides the first validation of sex steroid levels in P. virens. Post-ovulatory follicles were visible in histological sections from female gonads 9-11 months post-spawning, but then disappeared. Spawning commenced around a CL of c. 750 µm (700-800 µm). Hydrated oocytes (eggs) measured between 1·04 and 1·31 mm (mean = 1·18 mm) with decreasing sizes towards the end of spawning. The average estimated realized fecundity was c. 0·84 million eggs (median female total length, LT = 60 cm). Spawning lasted from 13 February to 29 March. [ABSTRACT FROM AUTHOR]

Published

2017

18. Estimating population size and habitat suitability for mountain nyala in areas with different protection status

Author

Atickem, A., primary, Loe, L. E., additional, Langangen, Ø., additional, Rueness, E. K., additional, Bekele, A., additional, and Stenseth, N. C., additional

Published

2011

19. SWAYING THREADS OF A SOLAR FILAMENT

Author

Lin, Y., primary, Soler, R., additional, Engvold, O., additional, Ballester, J. L., additional, Langangen, Ø., additional, Oliver, R., additional, and Rouppe van der Voort, L. H. M., additional

Published

2009

20. How fast could Usain Bolt have run? A dynamical study

Author

Eriksen, H. K., primary, Kristiansen, J. R., additional, Langangen, Ø., additional, and Wehus, I. K., additional

Published

2009

21. Search for High Velocities in the Disk Counterpart of Type II Spicules

Author

Langangen, Ø., primary, De Pontieu, B., additional, Carlsson, M., additional, Hansteen, V. H., additional, Cauzzi, G., additional, and Reardon, K., additional

Published

2008

22. Interaction between three key species in the sea ice-reduced Arctic Barents Sea system.

Author

Durant JM, Dupont N, Ono K, and Langangen Ø

Subjects

Animals, Arctic Regions, Gadiformes physiology, Gadus morhua physiology, Models, Biological, Ecosystem, Oceans and Seas, Ice Cover, Climate Change, Food Chain, Population Dynamics

Abstract

Population dynamics depend on trophic interactions that are affected by climate change. The rise in sea temperature is associated with the disappearance of sea ice in the Arctic. In the Arctic part of the Barents Sea, Atlantic cod, capelin and polar cod are three fish populations that interact and are confronted with climate-induced sea ice reductions. The first is a major predator in the system, while the last two are key species in Arctic and sub-Arctic ecosystems, respectively. There are still many unknowns regarding how predicted environmental change may influence the joint dynamics of these populations. Using time series from a 32 year long survey, we developed a state-space model that jointly modelled the dynamics of cod, capelin and polar cod. Using a hindcast scenario approach, we projected the effect of reduced sea ice on these populations. We show that the impact of sea ice reduction and concomitant sea temperature increase may lead to a decrease of polar cod abundance at the benefit of capelin but not of cod which may decrease, resulting in strong changes in the food web. Our analyses show that climate change in the Arcto-boreal system can generate different species assemblages and new trophic interactions, which is the knowledge needed for effective management measures.

Published

2024

23. Social and genetic connectivity despite ecological variation in a killer whale network.

Author

Jourdain E, Karoliussen R, Fordyce Martin SL, Langangen Ø, Robeck T, Borgå K, Ruus A, and Foote AD

Subjects

Animals, Social Behavior, Ecosystem, Predatory Behavior, Diet, Whale, Killer genetics

Abstract

Philopatric kin-based societies encourage a narrow breadth of conservative behaviours owing to individuals primarily learning from close kin, promoting behavioural homogeneity. However, weaker social ties beyond kin, and across a behaviourally diverse social landscape, could be sufficient to induce variation and a greater ecological niche breadth. We investigated a network of 457 photo-identified killer whales from Norway (548 encounters in 2008-2021) with diet data available (46 mixed-diet individuals feeding on both fish and mammals, and 411 exclusive fish-eaters) to quantify patterns of association within and between diet groups, and to identify underlying correlates. We genotyped a subset of 106 whales to assess patterns of genetic differentiation. Our results suggested kinship as main driver of social bonds within and among cohesive social units, while diet was most likely a consequence reflective of cultural diffusion, rather than a driver. Flexible associations within and between ecologically diverse social units led to a highly connected network, reducing social and genetic differentiation between diet groups. Our study points to a role of social connectivity, in combination with individual behavioural variation, in influencing population ecology in killer whales.

Published

2024

24. Large biomass reduction effect on the relative role of climate, fishing, and recruitment on fish population dynamics.

Author

Durant JM, Holt RE, and Langangen Ø

Subjects

Animals, Biomass, Hunting, Ecosystem, Population Dynamics, Fishes, Climate Change, Fisheries, Conservation of Natural Resources

Abstract

Many species around the world have collapsed, yet only some have recovered. A key question is what happens to populations post collapse. Traditionally, marine fish collapses are linked to overfishing, poor climate, and recruitment. We test whether the effect on biomass change from these drivers remains the same after a collapse. We used a regression model to analyse the effect of harvesting, recruitment, and climate variability on biomass change before and after a collapse across 54 marine fish populations around the world. The most salient result was the change in fishing effect that became weaker after a collapse. The change in sea temperature and recruitment effects were more variable across systems. The strongest changes were in the pelagic habitats. The resultant change in the sensitivity to external drivers indicates that whilst biomass may be rebuilt, the responses to variables known to affect stocks may have changed after a collapse. Our results show that a general model applied to many stocks provides useful insights, but that not all stocks respond similarly to a collapse calling for stock-specific models. Stocks respond to environmental drivers differently after a collapse, so caution is needed when using pre-collapse knowledge to advise on population dynamics and management., (© 2024. The Author(s).)

Published

2024

25. Persistence of fish populations to longer, more intense, and more frequent mass mortality events.

Author

Langangen Ø and Durant JM

Subjects

Animals, Population Dynamics, Biomass, Probability, Fishes, Climate Change

Abstract

Over the last decades, mass mortality events have become increasingly common across taxa with sometimes devastating effects on population biomass. In the aquatic environment, fish are sensitive to mass mortality events, particularly at the early life stages that are crucial for population dynamics. However, it has recently been shown for fish, that a single mass mortality event in early life typically does not lead to population collapse. Moreover, the frequency and intensity of extreme events that can cause mass mortality, such as marine heatwaves, are increasing. Here, we show that increasing frequency and intensity of mass mortality events may lead to population collapse. Since the drivers of mass mortality events are diverse, and often linked to climate change, it is challenging to predict the frequency and severity of future mass mortality events. As an alternative, we quantify the probability of population collapse depending on the frequency and intensity as well as the duration of mass mortality events. Based on 39 fish species, we show that the probability of collapse typically increases with increasing frequency, intensity, and duration of the mortality events. In addition, we show that the collapse depends on key traits such as natural mortality, recruitment variation, and density dependence. The presented framework provides quantitative estimates of the sensitivity of fish species to these increasingly common extreme events, which paves the way for potential mitigation actions to alleviate adverse impacts on harvested fish populations across the globe., (© 2024 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2024

26. Predatory walls may impair climate warming-associated population expansion.

Author

Durant JM, Holt RE, Ono K, and Langangen Ø

Subjects

Animals, Predatory Behavior, Climate Change, Ecosystem, Fishes

Abstract

Climate change has a profound impact on species distribution and abundance globally, as well as local diversity, which affects ecosystem functioning. In particular, changes in population distribution and abundance may lead to changes in trophic interactions. Although species can often shift their spatial distribution when suitable habitats are available, it has been suggested that predator presence can be a constraint on climate-related distribution shifts. We test this using two well-studied and data-rich marine environments. Focusing on a pair of sympatric fishes, Atlantic haddock Melanogrammus aeglefinus and cod Gadus morhua, we study the effect of the presence and abundance of the latter on the former distribution. We found that the distribution of cod and increased abundance may limit the expansion of haddock to new areas and could consequently buffer ecosystem changes due to climate change. Though marine species may track the rate and direction of climate shifts, our results demonstrate that the presence of predators may limit their expansion to thermally suitable habitats. By integrating climatic and ecological data at scales that can resolve predator-prey relationships, this analysis demonstrates the usefulness of considering trophic interactions to gain a more comprehensive understanding and to mitigate the effects of climate change on species distributions., (© 2023 The Authors. Ecology published by Wiley Periodicals LLC on behalf of The Ecological Society of America.)

Published

2023

27. Empirical evidence of nonlinearity in bottom up effect in a marine predator-prey system.

Author

Durant JM, Ono K, and Langangen Ø

Subjects

Animals, Food Chain, Population Dynamics, Predatory Behavior, Ecosystem, Osmeriformes

Abstract

The strength of species interactions may have profound effects on population dynamics. Empirical estimates of interaction strength are often based on the assumption that the interaction strengths are constant. Barents Sea (BS) cod and capelin are two fish populations for which such an interaction has been acknowledged and used, under the assumption of constant interaction strength, when studying their population dynamics. However, species interactions can often be nonlinear in marine ecosystems and might profoundly change our understanding of food chains. Analysing long-term time series data comprising a survey over 37 years in the Arcto-boreal BS, using a state-space modelling framework, we demonstrate that the effect of capelin on cod is not linear but shifts depending on capelin abundance: while capelin is beneficial for cod populations at high abundance; below the threshold, it becomes less important for cod. Our analysis therefore shows the importance of investigating nonlinearity in species interactions and may contribute to an improved understanding on species assemblages.

Published

2022

28. Age structure affects population productivity in an exploited fish species.

Author

Ohlberger J, Langangen Ø, and Stige LC

Subjects

Animals, Climate Change, Female, Population Dynamics, Reproduction, Fisheries, Gadus morhua physiology

Abstract

Long-term changes in the age and size structure of animal populations are well documented, yet their impacts on population productivity are poorly understood. Fishery exploitation can be a major driver of changes in population age-size structure because fisheries significantly increase mortality and often selectively remove larger and older fish. Climate change is another potential driver of shifts in the demographic structure of fish populations. Northeast Arctic (NEA) cod is the largest population of Atlantic cod (Gadus morhua) and one of the world's most important commercial fish stocks. This population has experienced considerable changes in population age-size structure over the past century, largely in response to fishing. In this study, we investigate whether changes in spawner age structure have affected population productivity in NEA cod, measured as recruits per spawning stock biomass, over the past 75 years. We find evidence that shifts in age structure toward younger spawners negatively affect population productivity, implying higher recruitment success when the spawning stock is composed of older individuals. The positive effect of an older spawning stock is likely linked to maternal effects and higher reproductive output of larger females. Our results indicate a threefold difference in productivity between the youngest and oldest spawning stock that has been observed since the 1950s. Further, our results suggest a positive effect of environmental temperature and a negative effect of intraspecific cannibalism by older juveniles on population productivity, which partly masked the effect of spawner age structure unless accounted for in the model. Collectively, these findings emphasize the importance of population age structure for the productivity of fish populations and suggest that harvest-induced demographic changes can have negative feedbacks for fisheries that lead to a younger spawning stock. Incorporating demographic data into harvest strategies could thus facilitate sustainable fishery management., (© 2022 The Ecological Society of America.)

Published

2022

29. Stock collapse and its effect on species interactions: Cod and herring in the Norwegian-Barents Seas system as an example.

Author

Durant JM, Aarvold L, and Langangen Ø

Abstract

Both the Norwegian Spring Spawning herring ( Clupea harengus ) and the Northeast Arctic (NEA) cod ( Gadus morhua ) are examples of strong stock reduction and decline of the associated fisheries due to overfishing followed by a recovery. Cod and herring are both part of the Barents Sea ecosystem, which has experienced major warming events in the early (1920-1940) and late 20th century. While the collapse or near collapse of these stocks seems to be linked to an instability created by overfishing and climate, the difference of population dynamics before and after is not fully understood. In particular, it is unclear how the changes in population dynamics before and after the collapses are associated with biotic interactions. The combination of the availability of unique long-term time series for herring and cod makes it a well-suited study system to investigate the effects of collapse. We examine how species interactions may differently affect the herring and cod population dynamic before and after a collapse. Particularly we explore, using a GAM modeling approach, how herring could affect cod and vice versa . We found that the effect of cod biomass on herring that was generally positive (i.e., covariation) but the effect became negative after the collapse (i.e., predation or competition). Likewise a change occurred for the cod, the juvenile herring biomass that had no effect before the collapse had a negative effect after. Our results indicate that the population collapses may alter the inter-specific interactions and response to abiotic environmental changes. While the stocks are at similar abundance levels before and after the collapses, the system is potentially different in its functioning and may require different management action., Competing Interests: The authors have no conflicts of interest to report., (© 2021 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.)

Published

2021

30. Nonlinearity in interspecific interactions in response to climate change: Cod and haddock as an example.

Author

Durant JM, Ono K, Stenseth NC, and Langangen Ø

Subjects

Animals, Bayes Theorem, Ecosystem, Population Dynamics, Climate Change, Gadiformes

Abstract

Climate change has profound ecological effects, yet our understanding of how trophic interactions among species are affected by climate change is still patchy. The sympatric Atlantic haddock and cod are co-occurring across the North Atlantic. They compete for food at younger stages and thereafter the former is preyed by the latter. Climate change might affect the interaction and coexistence of these two species. Particularly, the increase in sea temperature (ST) has been shown to affect distribution, population growth and trophic interactions in marine systems. We used 33-year long time series of haddock and cod abundances estimates from two data sources (acoustic and trawl survey) to analyse the dynamic effect of climate on the coexistence of these two sympatric species in the Arcto-Boreal Barents Sea. Using a Bayesian state-space threshold model, we demonstrated that long-term climate variation, as expressed by changes of ST, affected species demography through different influences on density-independent processes. The interaction between cod and haddock has shifted in the last two decades due to an increase in ST, altering the equilibrium abundances and the dynamics of the system. During warm years (ST over ca. 4°C), the increase in the cod abundance negatively affected haddock abundance while it did not during cold years. This change in interactions therefore changed the equilibrium population size with a higher population size during warm years. Our analyses show that long-term climate change in the Arcto-Boreal system can generate differences in the equilibrium conditions of species assemblages., (© 2020 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2020

31. Size- and stage-dependence in cause-specific mortality of migratory brown trout.

Author

Nater CR, Vindenes Y, Aass P, Cole D, Langangen Ø, Moe SJ, Rustadbakken A, Turek D, Vøllestad LA, and Ergon T

Subjects

Animals, Body Size, Cause of Death, Norway, Trout

Abstract

Evidence-based management of natural populations under strong human influence frequently requires not only estimates of survival but also knowledge about how much mortality is due to anthropogenic vs. natural causes. This is the case particularly when individuals vary in their vulnerability to different causes of mortality due to traits, life history stages, or locations. Here, we estimated harvest and background (other cause) mortality of landlocked migratory salmonids over half a century. In doing so, we quantified among-individual variation in vulnerability to cause-specific mortality resulting from differences in body size and spawning location relative to a hydropower dam. We constructed a multistate mark-recapture model to estimate harvest and background mortality hazard rates as functions of a discrete state (spawning location) and an individual time-varying covariate (body size). We further accounted for among-year variation in mortality and migratory behaviour and fit the model to a unique 50-year time series of mark-recapture-recovery data on brown trout (Salmo trutta) in Norway. Harvest mortality was highest for intermediate-sized trout, and outweighed background mortality for most of the observed size range. Background mortality decreased with body size for trout spawning above the dam and increased for those spawning below. All vital rates varied substantially over time, but a trend was evident only in estimates of fishers' reporting rate, which decreased from over 50% to less than 10% throughout the study period. We highlight the importance of body size for cause-specific mortality and demonstrate how this can be estimated using a novel hazard rate parameterization for mark-recapture models. Our approach allows estimating effects of individual traits and environment on cause-specific mortality without confounding, and provides an intuitive way to estimate temporal patterns within and correlation among different mortality sources., (© 2020 The Authors. Journal of Animal Ecology published by John Wiley & Sons Ltd on behalf of British Ecological Society.)

Published

2020

32. Population variability under stressors is dependent on body mass growth and asymptotic body size.

Author

Färber L, van Gemert R, Langangen Ø, Durant JM, and Andersen KH

Abstract

The recruitment and biomass of a fish stock are influenced by their environmental conditions and anthropogenic pressures such as fishing. The variability in the environment often translates into fluctuations in recruitment, which then propagate throughout the stock biomass. In order to manage fish stocks sustainably, it is necessary to understand their dynamics. Here, we systematically explore the dynamics and sensitivity of fish stock recruitment and biomass to environmental noise. Using an age-structured and trait-based model, we explore random noise (white noise) and autocorrelated noise (red noise) in combination with low to high levels of harvesting. We determine the vital rates of stocks covering a wide range of possible body mass (size) growth rates and asymptotic size parameter combinations. Our study indicates that the variability of stock recruitment and biomass are probably correlated with the stock's asymptotic size and growth rate. We find that fast-growing and large-sized fish stocks are likely to be less vulnerable to disturbances than slow-growing and small-sized fish stocks. We show how the natural variability in fish stocks is amplified by fishing, not just for one stock but for a broad range of fish life histories., Competing Interests: The authors declare no competing interests., (© 2020 The Authors.)

Published

2020

33. Effects of size- and sex-selective harvesting: An integral projection model approach.

Author

Stubberud MW, Vindenes Y, Vøllestad LA, Winfield IJ, Stenseth NC, and Langangen Ø

Abstract

Harvesting is often size-selective, and in species with sexual size dimorphism, it may also be sex-selective. A powerful approach to investigate potential consequences of size- and/or sex-selective harvesting is to simulate it in a demographic population model. We developed a population-based integral projection model for a size- and sex-structured species, the commonly exploited pike ( Esox lucius ). The model allows reproductive success to be proportional to body size and potentially limited by both sexes. We ran all harvest simulations with both lower size limits and slot limits, and to quantify the effects of selective harvesting, we calculated sex ratios and the long-term population growth rate ( λ ). In addition, we quantified to what degree purely size-selective harvesting was sex-selective, and determined when λ shifted from being female to male limited under size- and sex-selective harvesting. We found that purely size-selective harvest can be sex-selective, and that it depends on the harvest limits and the size distributions of the sexes. For the size- and sex-selective harvest simulations, λ increased with harvest intensity up to a threshold as females limited reproduction. Beyond this threshold, males became the limiting sex, and λ decreased as more males were harvested. The peak in λ , and the corresponding sex ratio in harvest, varied with both the selectivity and the intensity of the harvest simulation. Our model represents a useful extension of size-structured population models as it includes both sexes, relaxes the assumption of female dominance, and accounts for size-dependent fecundity. The consequences of selective harvesting presented here are especially relevant for size- and sex-structured exploited species, such as commercial fisheries. Thus, our model provides a useful contribution toward the development of more sustainable harvesting regimes., Competing Interests: None declared., (© 2019 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.)

Published

2019

34. Contrasting effects of rising temperatures on trophic interactions in marine ecosystems.

Author

Durant JM, Molinero JC, Ottersen G, Reygondeau G, Stige LC, and Langangen Ø

Subjects

Animals, Ecosystem, Food Chain, Models, Biological, Fishes physiology, Global Warming, Predatory Behavior, Zooplankton physiology

Abstract

In high-latitude marine environments, primary producers and their consumers show seasonal peaks of abundance in response to annual light cycle, water column stability and nutrient availability. Predatory species have adapted to this pattern by synchronising life-history events such as reproduction with prey availability. However, changing temperatures may pose unprecedented challenges by decoupling the predator-prey interactions. Here we build a predator-prey model accounting for the full life-cycle of fish and zooplankton including their phenology. The model assumes that fish production is bottom-up controlled by zooplankton prey abundance and match or mismatch between predator and prey phenology, and is parameterised based on empirical findings of how climate influences phenology and prey abundance. With this model, we project possible climate-warming effects on match-mismatch dynamics in Arcto-boreal and temperate biomes. We find a strong dependence on synchrony with zooplankton prey in the Arcto-boreal fish population, pointing towards a possible pronounced population decline with warming because of frequent desynchronization with its zooplankton prey. In contrast, the temperate fish population appears better able to track changes in prey timing and hence avoid strong population decline. These results underline that climate change may enhance the risks of predator-prey seasonal asynchrony and fish population declines at higher latitudes.

Published

2019

35. Improving risk assessments in conservation ecology.

Author

Ono K, Langangen Ø, and Stenseth NC

Subjects

Animals, Ecology, Humans, Models, Statistical, Population Density, Population Dynamics, Conservation of Natural Resources, Risk Assessment methods

Abstract

Conservation efforts and management decisions on the living environment of our planet often rely on the results from statistical models. Yet, these models are imperfect and quantification of risk associated with the estimate of management-relevant quantities becomes crucial in providing robust advice. Here we demonstrate that estimates of risk themselves could be substantially biased but by combining data fitting with an extensive simulation-estimation procedure, one can back-calculate the correct values. We apply the method to 627 time series of population abundance across four taxa using the Gompertz state-space model as an example. We find that the risk of large bias in population status estimate increases with the species' growth rate, population variability, weaker density dependence, and shorter time series, across taxa. We urge scientists dealing with conservation and management to adopt a similar approach to ensure a more accurate estimate of risk measures and contribute towards a precautionary approach to management.

Published

2019

36. Ticket to spawn: Combining economic and genetic data to evaluate the effect of climate and demographic structure on spawning distribution in Atlantic cod.

Author

Langangen Ø, Färber L, Stige LC, Diekert FK, Barth JMI, Matschiner M, Berg PR, Star B, Stenseth NC, Jentoft S, and Durant JM

Subjects

Animals, Atlantic Ocean, Gadus morhua genetics, Norway, Animal Distribution, Climate Change, Fisheries economics, Gadus morhua physiology, Reproduction

Abstract

Climate warming and harvesting affect the dynamics of species across the globe through a multitude of mechanisms, including distribution changes. In fish, migrations to and distribution on spawning grounds are likely influenced by both climate warming and harvesting. The Northeast Arctic (NEA) cod (Gadus morhua) performs seasonal migrations from its feeding grounds in the Barents Sea to spawning grounds along the Norwegian coast. The distribution of cod between the spawning grounds has historically changed at decadal scales, mainly due to variable use of the northern and southern margins of the spawning area. Based on historical landing records, two major hypotheses have been put forward to explain these changes: climate and harvesting. Climate could affect the distribution through, for example, spatial habitat shifts. Harvesting could affect the distribution through impacting the demographic structure. If demographic structure is important, theory predicts increasing spawner size with migration distance. Here, we evaluate these hypotheses with modern data from a period (2000-2016) of increasing temperature and recovering stock structure. We first analyze economic data from the Norwegian fisheries to investigate geographical differences in size of spawning fish among spawning grounds, as well as interannual differences in mean latitude of spawning in relation to changes in temperature and demographic parameters. Second, we analyze genetically determined fish sampled at the spawning grounds to unambiguously separate between migratory NEA cod and potentially smaller sized coastal cod of local origin. Our results indicate smaller spawners farther away from the feeding grounds, hence not supporting the hypothesis that harvesting is a main driver for the contemporary spawning ground distribution. We find a positive correlation between annual mean spawning latitude and temperature. In conclusion, based on contemporary data, there is more support for climate compared to harvesting in shaping spawning ground distribution in this major fish stock in the North Atlantic Ocean., (© 2018 John Wiley & Sons Ltd.)

Published

2019

37. Individual heterogeneity and early life conditions shape growth in a freshwater top predator.

Author

Nater CR, Rustadbakken A, Ergon T, Langangen Ø, Moe SJ, Vindenes Y, Vøllestad LA, and Aass P

Subjects

Animals, Bayes Theorem, Body Size, Trout, Ecology, Fresh Water

Abstract

Body size can have profound impacts on survival, movement, and reproductive schedules shaping individual fitness, making growth a central process in ecological and evolutionary dynamics. Realized growth is the result of a complex interplay between life history schedules, individual variation, and environmental influences. Integrating all of these aspects into growth models is methodologically difficult, depends on the availability of repeated measurements of identifiable individuals, and consequently represents a major challenge in particular for natural populations. Using a unique 30-yr time series of individual length measurements inferred from scale year rings of wild brown trout, we develop a Bayesian hierarchical model to estimate individual growth trajectories in temporally and spatially varying environments. We reveal a gradual decrease in average juvenile growth, which has carried over to adult life and contributed to decreasing sizes observed at the population level. Commonly studied environmental drivers like temperature and water flow did not explain much of this trend and overall persistent and among-year individual variation dwarfed temporal variation in growth patterns. Our model and results are relevant to a wide range of questions in ecology and evolution requiring a detailed understanding of growth patterns, including conservation and management of many size-structured populations., (© 2018 by the Ecological Society of America.)

Published

2018

38. Combined effects of fishing and oil spills on marine fish: Role of stock demographic structure for offspring overlap with oil.

Author

Stige LC, Ottersen G, Yaragina NA, Vikebø FB, Stenseth NC, and Langangen Ø

Subjects

Animals, Arctic Regions, Computer Simulation, Population Dynamics, Reproduction, Conservation of Natural Resources methods, Environmental Monitoring methods, Fisheries, Gadus morhua growth & development, Petroleum Pollution adverse effects

Abstract

It has been proposed that the multiple pressures of fishing and petroleum activities impact fish stocks in synergy, as fishing-induced demographic changes in a stock may lead to increased sensitivity to detrimental effects of acute oil spills. High fishing pressure may erode the demographic structure of fish stocks, lead to less diverse spawning strategies, and more concentrated distributions of offspring in space and time. Hence an oil spill may potentially hit a larger fraction of a year-class of offspring. Such a link between demographic structure and egg distribution was recently demonstrated for the Northeast Arctic stock of Atlantic cod for years 1959-1993. We here estimate that this variation translates into a two-fold variation in the maximal proportion of cod eggs potentially exposed to a large oil spill. With this information it is possible to quantitatively account for demographic structure in prospective studies of population effects of possible oil spills., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

39. Predator-prey interactions cause apparent competition between marine zooplankton groups.

Author

Stige LC, Kvile KØ, Bogstad B, and Langangen Ø

Subjects

Animals, Biomass, Climate Change, Fishes, Population Dynamics, Ecosystem, Zooplankton

Abstract

Predator-mediated apparent competition is an indirect negative interaction between two prey species mediated by a shared predator. Quantifying such indirect ecosystem effects is methodologically challenging but important for understanding ecosystem functioning. Still, there are few examples of apparent competition from pelagic marine environments. Using state-space statistical modeling, we here provide evidence for apparent competition between two dominant zooplankton groups in a large marine ecosystem, i.e., krill and copepods in the Barents Sea. This effect is mediated by a positive association between krill biomass and survival of the main planktivorous fish in the Barents Sea, capelin Mallotus villosus, and a negative association between capelin and copepod biomasses. The biomass of Atlantic krill species is expected to increase in the Barents Sea due to ongoing climate change, thereby potentially negatively affecting copepods through apparent competition. By demonstrating and quantifying apparent competition in a large marine ecosystem, our study paves the way for more realistic projections of indirect ecosystem effects of climate change and harvesting., (© 2017 by the Ecological Society of America.)

Published

2018

40. Effect of a fish stock's demographic structure on offspring survival and sensitivity to climate.

Author

Stige LC, Yaragina NA, Langangen Ø, Bogstad B, Stenseth NC, and Ottersen G

Subjects

Animals, Female, Geography, Larva physiology, Male, Norway, Oceans and Seas, Ovum physiology, Population Dynamics, Population Growth, Russia, Climate, Conservation of Natural Resources methods, Fisheries, Gadus morhua physiology

Abstract

Commercial fishing generally removes large and old individuals from fish stocks, reducing mean age and age diversity among spawners. It is feared that these demographic changes lead to lower and more variable recruitment to the stocks. A key proposed pathway is that juvenation and reduced size distribution causes reduced ranges in spawning period, spawning location, and egg buoyancy; this is proposed to lead to reduced spatial distribution of fish eggs and larvae, more homogeneous ambient environmental conditions within each year-class, and reduced buffering against negative environmental influences. However, few, if any, studies have confirmed a causal link from spawning stock demographic structure through egg and larval distribution to year class strength at recruitment. We here show that high mean age and size in the spawning stock of Barents Sea cod (Gadus morhua) is positively associated with high abundance and wide spatiotemporal distribution of cod eggs. We find, however, no support for the hypothesis that a wide egg distribution leads to higher recruitment or a weaker recruitment-temperature correlation. These results are based on statistical analyses of a spatially resolved data set on cod eggs covering a period (1959-1993) with large changes in biomass and demographic structure of spawners. The analyses also account for significant effects of spawning stock biomass and a liver condition index on egg abundance and distribution. Our results suggest that the buffering effect of a geographically wide distribution of eggs and larvae on fish recruitment may be insignificant compared with other impacts., Competing Interests: The authors declare no conflict of interest.

Published

2017

41. Cascading effects of mass mortality events in Arctic marine communities.

Author

Langangen Ø, Ohlberger J, Stige LC, Durant JM, Ravagnan E, Stenseth NC, and Hjermann DØ

Subjects

Animals, Arctic Regions, Bayes Theorem, Environmental Pollution, Food Chain, Environmental Monitoring, Fishes, Zooplankton

Abstract

Mass mortality events caused by pulse anthropogenic or environmental perturbations (e.g., extreme weather, toxic spills or epizootics) severely reduce the abundance of a population in a short time. The frequency and impact of these events are likely to increase across the globe. Studies on how such events may affect ecological communities of interacting species are scarce. By combining a multispecies Gompertz model with a Bayesian state-space framework, we quantify community-level effects of a mass mortality event in a single species. We present a case study on a community of fish and zooplankton in the Barents Sea to illustrate how a mass mortality event of different intensities affecting the lower trophic level (krill) may propagate to higher trophic levels (capelin and cod). This approach is especially valuable for assessing community-level effects of potential anthropogenic-driven mass mortality events, owing to the ability to account for uncertainty in the assessed impact due to uncertainty about the ecological dynamics. We hence quantify how the assessed impact of a mass mortality event depends on the degree of precaution considered. We suggest that this approach can be useful for assessing the possible detrimental outcomes of toxic spills, for example oil spills, in relatively simple communities such as often found in the Arctic, a region under increasing influence of human activities due to increased land and sea use., (© 2016 John Wiley & Sons Ltd.)

Published

2017

42. Timecourse of oocyte development in saithe Pollachius virens.

Author

Skjaeraasen JE, Devine JA, Godiksen JA, Fonn M, OtterÅ H, Kjesbu OS, Norberg B, Langangen Ø, and Karlsen Ø

Subjects

Animals, Female, Fertility physiology, Gadiformes anatomy & histology, Gadiformes blood, Gonadal Steroid Hormones blood, Male, North Sea, Oocytes cytology, Oocytes growth & development, Seasons, Vitellogenesis physiology, Gadiformes growth & development, Oogenesis physiology

Abstract

Wild caught North Sea saithe Pollachius virens were monitored for growth, sex steroid profiles and oocyte development pre-spawning and measured for egg size and group fecundity during the spawning season in the laboratory. Vitellogenesis commenced in late October-early November, at a leading cohort size (C L ) of c. 250 µm, after which oocytes grew rapidly in size until spawning started in February. Notably, a distinct cortical alveoli stage was virtually absent with yolk granules observed in developing oocytes at the very beginning of vitellogenesis. Little atresia was observed pre-spawning, but atretic re-absorption of remnant oocytes containing yolk granules was found in all females immediately post-spawning. As expected, concentrations of sex steroids, oestradiol-17β (females), testosterone (both sexes) and 11-ketotestosterone (both sexes), increased pre-spawning before dropping post-spawning. The present experiment provides the first validation of sex steroid levels in P. virens. Post-ovulatory follicles were visible in histological sections from female gonads 9-11 months post-spawning, but then disappeared. Spawning commenced around a C L of c. 750 µm (700-800 µm). Hydrated oocytes (eggs) measured between 1·04 and 1·31 mm (mean = 1·18 mm) with decreasing sizes towards the end of spawning. The average estimated realized fecundity was c. 0·84 million eggs (median female total length, L T = 60 cm). Spawning lasted from 13 February to 29 March., (© 2016 The Fisheries Society of the British Isles.)

Published

2017

43. Fitness consequences of early life conditions and maternal size effects in a freshwater top predator.

Author

Vindenes Y, Langangen Ø, Winfield IJ, and Vøllestad LA

Subjects

Animals, Ecosystem, Female, Fresh Water, Population Dynamics, Predatory Behavior, Body Size, Esocidae growth & development, Esocidae physiology, Ovum

Abstract

Conditions experienced in early life stages can be an important determinant of individual life histories. In fish, environmental conditions are known to affect early survival and growth, but recent studies have also emphasized maternal effects mediated by size or age. However, the relative sensitivity of the mean fitness (population growth rate λ) to different early life impacts remains largely unexplored. Using a female-based integral projection model (IPM) parameterized from unique long-term demographic data for pike (Esox lucius), we evaluated the relative fitness consequences of different early life impacts, including (i) maternal effects of length on egg weight, potentially affecting offspring (first year) survival, and (ii) effects of temperature on offspring growth and survival. Of the seven vital rates defining the model, offspring survival could not be directly estimated and four scenarios were defined for this rate. Elasticity analyses of the IPM were performed to calculate (i) the total contribution from different lengths to the elasticity of λ to the projection kernel, and (ii) the elasticity of λ to underlying variables of female current length, female offspring length at age 1, and temperature. These elasticities were decomposed into contributions from different vital rates across length. Egg weight increased with female length, as expected, but the effect leveled off for the largest females. However, λ was largely insensitive to this effect, even when egg weight was assumed to have a strong effect on offspring survival. In contrast, λ was sensitive to early temperature conditions through growth and survival. Among mature females, the total elasticity of λ to the projection kernel generally increased with length. The results were robust to a wide range of assumptions. These results suggest that environmental conditions experienced in early life represent a more important driver of mean population growth and fitness of pike than maternal effects of size on offspring survival. We discuss two general mechanisms underlying the weak influence of this maternal effect, suggesting that these may be general for long-lived and highly fecund fishes. This model and results are relevant for the management of long-lived top predators, including many commercially important fish species., (© 2016 The Authors. Journal of Animal Ecology © 2016 British Ecological Society.)

Published

2016

44. Disentangling the mechanisms behind climate effects on zooplankton.

Author

Kvile KØ, Langangen Ø, Prokopchuk I, Stenseth NC, and Stige LC

Subjects

Animals, Biomass, Chlorophyll metabolism, Ecosystem, Zooplankton metabolism, Climate, Zooplankton growth & development

Abstract

Understanding how climate influences ecosystems is complicated by the many correlated and interrelated impacting factors. Here we quantify climate effects on Calanus finmarchicus in the northeastern Norwegian Sea and southwestern Barents Sea. By combining oceanographic drift models and statistical analyses of field data from 1959 to 1993 and investigating effects across trophic levels, we are able to elucidate pathways by which climate influences zooplankton. The results show that both chlorophyll biomass in spring and C. finmarchicus biomass in summer relate positively to a combination of shallow mixed layer depth and increased wind in spring, suggesting that C. finmarchicus biomass in summer is influenced by bottom-up effects of food availability. Furthermore, spatially resolved C. finmarchicus biomass in summer is linked to favorable transport from warmer, core areas to the south. However, increased mean temperature in spring does not lead to increased C. finmarchicus biomass in summer. Rather, spring biomass is generally higher, but population growth from spring to summer is lower, after a warm compared with a cold spring. Our study illustrates how improved understanding of climate effects can be obtained when different datasets and different methods are combined in a unified approach.

Published

2016

45. Population resilience to catastrophic mortality events during early life stages.

Author

Ohlberger J and Langangen Ø

Subjects

Aging, Animals, Biomass, Environmental Monitoring, Larva, Models, Biological, Ovum, Population Density, Population Dynamics, Time Factors, Ecosystem, Gadiformes physiology

Abstract

Catastrophic mortality events that drastically reduce the abundance of a population or a particular life stage can have long-term ecological and economic effects, and are of great concern in species conservation and management. Severe die-offs may be caused by natural catastrophes such as disease outbreaks and extreme climates, or human-caused disturbances such as toxic spills. Forecasting potential impacts of such disturbances is difficult and highly uncertain due to unknown future conditions, including population status and environmental conditions at the time of impact. Here, we present a framework for quantifying the range of potential, population-level effects of catastrophic events based on a hindcasting approach. A dynamic population model with Bayesian parameter estimation is used to simulate the impact of severe (50-99%) mortality events during the early life stages of Northeast Arctic cod (Gadus morhua), an abundant marine fish population of high economic value. We quantify the impact of such die-offs in terms of subsequent changes in population biomass and harvest through direct comparison of simulated and historical trends, and estimate the duration of the impact as a measure of population resilience. Our results demonstrate strong resilience to catastrophic events that affect early life stages owing to density dependence in survival and a broad population age structure. Yet, while population recovery is. relatively fast, losses in harvest and economic value can be substantial. Future research efforts should focus on long-term and indirect effects via food web interactions in order to better understand the ecological and economic ramifications of catastrophic mortality events.

Published

2015

46. Individual heterogeneity in life histories and eco-evolutionary dynamics.

Author

Vindenes Y and Langangen Ø

Subjects

Animals, Ecology methods, Esocidae genetics, Esocidae physiology, Population Dynamics, Quantitative Trait, Heritable, Biological Evolution, Climate Change, Models, Biological

Abstract

Individual heterogeneity in life history shapes eco-evolutionary processes, and unobserved heterogeneity can affect demographic outputs characterising life history and population dynamical properties. Demographic frameworks like matrix models or integral projection models represent powerful approaches to disentangle mechanisms linking individual life histories and population-level processes. Recent developments have provided important steps towards their application to study eco-evolutionary dynamics, but so far individual heterogeneity has largely been ignored. Here, we present a general demographic framework that incorporates individual heterogeneity in a flexible way, by separating static and dynamic traits (discrete or continuous). First, we apply the framework to derive the consequences of ignoring heterogeneity for a range of widely used demographic outputs. A general conclusion is that besides the long-term growth rate lambda, all parameters can be affected. Second, we discuss how the framework can help advance current demographic models of eco-evolutionary dynamics, by incorporating individual heterogeneity. For both applications numerical examples are provided, including an empirical example for pike. For instance, we demonstrate that predicted demographic responses to climate warming can be reversed by increased heritability. We discuss how applications of this demographic framework incorporating individual heterogeneity can help answer key biological questions that require a detailed understanding of eco-evolutionary dynamics., (© 2015 John Wiley & Sons Ltd/CNRS.)

Published

2015

47. Stage-specific biomass overcompensation by juveniles in response to increased adult mortality in a wild fish population.

Author

Ohlberger J, Langangen Ø, Edeline E, Claessen D, Winfield IJ, Stenseth NC, and Vøllestad LA

Subjects

Animals, United Kingdom, Biomass, Fish Diseases mortality, Models, Biological, Perches growth & development

Abstract

Recently developed theoretical models of stage-structured consumer-resource systems have shown that stage-specific biomass overcompensation can arise in response to increased mortality rates. We parameterized a stage-structured population model to simulate the effects of increased adult mortality caused by a pathogen outbreak in the perch (Perca fluviatilis) population of Windermere (UK) in 1976. The model predicts biomass overcompensation by juveniles in response to increased adult mortality due to a shift in food-dependent growth and reproduction rates. Considering cannibalism between life stages in the model reinforces this compensatory response due to the release from predation on juveniles at high mortality rates. These model predictions are matched by our analysis of a 60-year time series of scientific monitoring of Windermere perch, which shows that the pathogen outbreak induced a strong decrease in adult biomass and a corresponding increase in juvenile biomass. Age-specific adult fecundity and size at age were higher after than before the disease outbreak, suggesting that the pathogen-induced mortality released adult perch from competition, thereby increasing somatic and reproductive growth. Higher juvenile survival after the pathogen outbreak due to a release from cannibalism likely contributed to the observed biomass overcompensation. Our findings have general implications for predicting population- and community-level responses to increased size-selective mortality caused by exploitation or disease outbreaks.

Published

2011

48. Pathogen-induced rapid evolution in a vertebrate life-history trait.

Author

Ohlberger J, Langangen Ø, Edeline E, Olsen EM, Winfield IJ, Fletcher JM, James JB, Stenseth NC, and Vøllestad LA

Subjects

Animals, Body Size, England epidemiology, Logistic Models, Longitudinal Studies, Mycoses epidemiology, Time Factors, Biological Evolution, Fish Diseases epidemiology, Fish Diseases microbiology, Mycoses veterinary, Perches, Phenotype, Sexual Maturation physiology

Abstract

Anthropogenic factors, including climate warming, are increasing the incidence and prevalence of infectious diseases worldwide. Infectious diseases caused by pathogenic parasites can have severe impacts on host survival, thereby altering the selection regime and inducing evolutionary responses in their hosts. Knowledge about such evolutionary consequences in natural populations is critical to mitigate potential ecological and economic effects. However, studies on pathogen-induced trait changes are scarce and the pace of evolutionary change is largely unknown, particularly in vertebrates. Here, we use a time series from long-term monitoring of perch to estimate temporal trends in the maturation schedule before and after a severe pathogen outbreak. We show that the disease induced a phenotypic change from a previously increasing to a decreasing size at maturation, the most important life-history transition in animals. Evolutionary rates imposed by the pathogen were high and comparable to those reported for populations exposed to intense human harvesting. Pathogens thus represent highly potent drivers of adaptive phenotypic evolution in vertebrates.

Published

2011