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Research project PlantFish

PlantFish is a three year research project about the role of interactions between benthic plants and large predatory fish in coastal areas of the Baltic Sea. The project examines the functional role of vegetation and predatory fish and how they interact, with focus on the ecosystems of shallow Baltic Sea bays.

Ulf Bergström snorkels during juvenile fish and vegetation inventory in one of the 32 intensively studied bays. Photo: Göran Sundblad.

A male stickleback (Gasterosteus aculeatus) during spawning time. Photo: Joakim Hansen/Azote.

Coastal manager’s struggle globally both with declining stocks of large predatory fish and decreased submerged vegetation; the "foundation species" that forms the basis for many coastal ecosystems. The research project Plant-Fish has thoroughly examined the functional role of vegetation and predatory fish in a large number of shallow Baltic Sea bays.

The researchers in the project have combined studies at different spatial scales and methods to address the hypothesis that vegetation and predatory fish facilitate each other via a positive feedback loop, which enhances ecosystem health.

Plant-Fish is a co-operation between researchers at the Department of Ecology, Environment and Plant Sciences at Stockholms University, Stockholms University Baltic Sea Centre, Swedish University of Agricultural Sciences, University of Groningen and AquaBiota. The project was financed by the Swedish research council FORMAS during 2014-2018, and continues with the new project Spatially cascading regime shifts, the "stickleback wave".

Project description

A map showing all examined bays (blue) and the detaily studied bays (orange).

Modelling of vegetation and juvenile fish data across the entire Swedish Baltic Sea Coast have been combined with detailed examinations of the food web in 32 bays, and small-scale manipulative field experiments at the marine research station Askö Laboratory.

Results from the studies show that:

High cover of benthic vegetation results in less turbid water partly through stabilizing the soft sediment bottoms.
The benthic vegetation is important for coastal fish; the abundance of juveniles of pike, perch and cyprinids increase with increasing cover of vegetation.
Boat marinas have a negative effect on the cover and height of benthic vegetation, and alter the species composition. This can in turn influence the recruitment of fish.
Predatory fish, such as pike and perch, have a positive effect on benthic vegetation though a trophic cascade, where they control meso-predatory fish, such as sticklebacks, which in turn regulate small invertebrates such as insect larvae, snails and amphipods. These invertebrates can in turn, through grazing, control nuisance algae which smother the benthic vegetation.
The density of benthic vegetation is important for maintaining healthy plants when large predatory fish disappear and the water is enriched with excessive nutrients.
The small fish three-spined stickleback have gradually taken over larger parts of the Baltic Sea’s coastal ecosystem. The stickleback contributes to local ecosystem ‘regime shifts’, where young-of-the-year pike and perch decline in individual bays, and these shifts gradually spread like a wave, from the outer archipelago into the mainland coast. More stickleback and fewer predatory fish also intensifies the eutrophication symptoms, in accordance with the results above.

Strong links between vegetation and fish

Sampling in a shallow bay. Photo: Joakim Hansen.

The results from the project strengthen previous suggestions that the seabed vegetation perform important ecosystem functions such as improving water quality and recruitment success of coastal fish, whereas predatory fish indirectly control nuisance algae that otherwise smother the vegetation.

The research project have also documented the large-scale change that have occurred along the Swedish Baltic coast, where stickleback gradually have increased and caused local regime shifts in one bay after another; to a condition with few predatory fish and a lot of nuisance algae.

The jungle-like vegetation is perfect nursery habitats for fish like this young pike. Photo: Ulf Bergström.

Project members

Project managers

Johan Eklöf

Professor

Department of Ecology, Environment and Plant Sciences

johan.eklof@su.se

Members

Åsa Nilsson Austin

Forskare

Stockholm University Baltic Sea Centre

asa.austin@su.se

Serena Donadi

At the time of the project, postdoc at the Department of Ecology, Environment and Plant Sciences

Researcher at the Department of Aquatic Resources, SLU

serena.donadi@slu.se

Joakim Hansen

Environmental Analyst

Stockholm University Baltic Sea Centre

08-16 13 07

joakim.hansen@su.se

Klemens Britas Eriksson

Associate Professor Marine Ecology

Faculty of Science and Engineering, University of Groningen

b.d.h.k.eriksson@rug.nl

Ulf Bergström

Researcher

Department of Aquatic Resources, SLU Aqua

ulf.bergstrom@slu.se

Göran Sundblad

Researcher

Department of Aquatic Resources, SLU Aqua

goran.sundblad@slu.se

Publications

Åsa N. Austin, Joakim P. Hansen, Serena Donadi, Lena Kautsky, Johan S. Eklöf

Stronger effect of individual species’ traits than shading on aquatic plant community productivity and interspecific competition (2023)

J Eklöf, J Hansen, B K Eriksson, Ö Östman, Å Austin, C Yanos, R Fredriksson, U Bergström, H Andersso

Effects of seasonal spawning closures on pike (Esox lucius L.) and perch (Perca fluviatilis L.) catches and coastal food webs in the western Baltic Sea (2023)

Austin ÅN, Hansen JP, Donadi S, Bergström U, Eriksson BK, Sundblad G, Eklöf JS

Synergistic effects of rooted aquatic vegetation and drift wrack on ecosystem multifunctionality. Ecosystems (2021)

Yanos CL, Haanstra, EP, Colgan Carey, F, Passmore SA, Eklöf JS, Bergström U, Hansen JP, Fontaine MC,

Predator biomass and vegetation influence the coastal distribution of threespine stickleback morphotypes. Ecology and Evolution (2021)

Eriksson BK, Yanos C, Bourlat SJ, Donadi S, Fontaine MC, Hansen JP, Jakubavičiūtė E, Kiragosyan K, M

Habitat segregation of plate phenotypes in a rapidly expanding population of three-spined stickleback. Ecosphere 12 (6): e03561 (2021)

Relationships between aquatic vegetation and water turbidity: A field survey across seasons and spat

Åsa N. Austin, Joakim P. Hansen, Serena Donadi, Johan S. Eklöf, PLOS One, Published: August 30, 2017, https://doi.org/10.1371/journal.pone.0181419

DNA metabarcoding reveals diverse diet of the three-spined stickleback in a coastal ecosystem

Eglė Jakubavičiūtė, Ulf Bergström, Johan S. Eklöf, Quiterie Haenel, Sarah J. Bourlat, PLOS One, Published: October 23, 2017, https://doi.org/10.1371/journal.pone.0186929

A cross-scale trophic cascade from large predatory fish to algae in coastal ecosystems

Published: Proceedings of the Royal Society B: Biological Sciences, 19 July 2017https://doi.org/10.1098/rspb.2017.0045

A spatial regime shift from predator to prey dominance in a large coastal ecosystem

Johan S. Eklöf, Göran Sundblad, Mårten Erlandsson, Serena Donadi, Joakim P. Hansen, Britas Klemens Eriksson & Ulf Bergström, Communications Biology volume 3, Article number: 459 (2020)

The Stickleback Wave: a spatial regime shift from predator to prey dominance

Johan S. Eklöf, a blogpost in Nature Ecology and Evolution Community, Aug 27, 2020

Density dependent positive feedbacks buffer aquatic plants from interactive effects of ..

..eutrophication and predator loss Donadi, S. , Austin, Å. N., Svartgren, E. , Eriksson, B. K., Hansen, J. P. and Eklöf, J. S. (2018). Ecology. doi:10.1002/ecy.2501

Recreational boating degrades vegetation important for fish recruitment

Joakim P. Hansen, Göran Sundblad, Ulf Bergström, Åsa N. Austin, Serena Donadi, Britas Klemens Eriksson & Johan S. Eklöf. Ambio volume 48, pages 539–551 (2019)

More about this project

In shallow bays with many jetties and a lot of boat traffic the vegetation was both short and sparse, and the most sensitive species were missing. Photo: Joakim Hansen.

A spatial regime shift to stickleback dominance. Large numbers of three-spined stickleback have gradually taken over larger parts of the Baltic Sea’s coastal ecosystem, shows a new scientific study. Stickleback is a small prey fish common in aquatic food webs across temperate Europe. The stickleback contributes to local ecosystem ‘regime shifts’, where young-of-the-year pike and perch decline in individual bays, and these shifts gradually spread like a wave from the outer archipelago into the mainland coast.

The Project in English media

Science In depth, Sep 4, 2020, An ecosystem goes topsy-turvy as a tiny fish takes over

Science, Aug 27, 2020, A tiny fish takes on its predators—and wins, transforming the Baltic coast

For an overview over more coverage, in Swedish, see the Swedish project page.