DOCSLIB.ORG

BONUS BAMBI Year 1 Report

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
BONUS BAMBI Year 1 Report BAMBI -­­ Baltic Sea marine biodiversity – addressing the potential of adaptation to climate change implications – Grant Agreement number: call2012-­­76 PROJECT SUMMARY The overall goal of BAMBI is to assess and improve capacities of marine species to cope with the current challenge of a rapidly changing Baltic Sea environment. During decreased salinity and increased temperatures of the Baltic Sea, species with marine origin, in particular, will be under heavier physiological stress than before. This stress may result in local extinction, unless species are able to adapt to the new conditions. The goal of BAMBI is to perform research to be able to understand the potential of organisms to evolve new adaptations and how management should be framed to support this. In BAMBI we aim to answer these urgent questions: 1 Will species and ecosystems of marine origin adapt and survive the coming 50-100 years inside the Baltic Sea? 2 If so, what is needed in terms of population sizes, population connectivity and genetic variation? 3 What governance structures, policy instruments and management measures can mitigate losses of marine Baltic Sea species? To answer these questions requires a strong multi-disciplinary research effort that generates new scientific results reaching beyond current state-of-the-art. In addition, it requires an operational science-policy interface and a strong end-user involvement. The research programme BAMBI is designed to meet these demands through: integrating front-line research competences in genetics and genomics, population ecology, biophysical modelling, conservation genetic and political sciences using state-of-the-art research methods, such as next generation sequencing, population genomics, climate-driven and spatially explicit modelling actively involving end users, to combine science with practical knowledge throughout the project BAMBI is a four-year research project with partners from four different countries around the Baltic (Estonia, Finland, Germany and Sweden), and competences including from ecology, genetics, conservation biology, oceanography and political science. BAMBI will target four ecologically important Baltic Sea species that each contribute with different ecosystem functions (primary production, grazing, and predation), and together ! constitute a dominant part of a Baltic Sea ecosystem (Fig. 1). These species also work as experimentally tractable models for evolutionary studies. ! Fig. 1. The seaweeds (Fucus vesiculosus and F. radicans) are grazed upon by the isopod (Idotea balthica), that is eaten by the fish (Gasterosteus aculeatus), the fish using the seaweed to its nests. This model ecosystem constitutes a dominant part of coastal hard bottom ecosystems of the Baltic Sea. ! During the first year of the project (2014) we have achieved most of the sampling and fieldwork, according to plan. Thus we have: • Sampled 95% of the samples of Fucus vesiculosus and F. radicans, throughout their Baltic Sea range, including the Kattegat and reference samples in Skagerrak and the Atlantic. • Sampled 95% of the samples of Idotea balthica throughout its Baltic Sea range, including reference sites in Kattegat. • Sampled all samples of stickleback throughout its Baltic Sea range, including reference sites in Kattegat and North Sea. All these samples have been stored for DNA (RNA) extractions, a work that has also been started. In addition, we have improved and designed new (when necessary) protocols for DNA extraction and analyses, as quality of DNA is critical for the advanced genome-wide RAD sequencing to work. A test system for experimental manipulation of combined salinity and temperature for tolerance and gene expression experiments have been built and the first experiments have already been performed. Field surveys of distributions as well as manipulative tests to find out about environmental requirements for the two sibling species of Fucus have been achieved and additional distributional data have been gathered from all around the Baltic Sea to be used in predictive modelling. Oceanographic modelling of connectivity built on climate models from SMHI in combination with oceanographic dispersal trajectories have been performed. In addition, we now have various scenarios for climate changes for the Baltic Sea that will be further explored in modelling population connectivity for specific species. Experimental, in situ, measurements of short-distance coastal rafting were performed from sampling sites to simulate rafting of e.g. seaweeds. The political science and conservation genetics studies focus on marine conservation and marine protected areas in Nature 2000 and HELCOM MPAs. Interviews with stakeholders have been organized during this first year and analyses of these first sets of data are in ! ! progress. An important milestone is the establishment of an enduser group with representatives of several of the BAMBI-countries. " Snapshots from the field campaigns, summer 2014. Melanie Heckwolf from GEOMAR, Germany, and Luca Rugiu from University of Turku, Finland, catching sticklebacks close to the Archipelago Research Institute in Finland. ! ! # Pierre De Wit, University of Gothenburg, sampling of Fucus and Idotea outside Ottenby, south tip of Öland, Sweden. ! ! $ Samples of Idotea baltica ! ! % ! Luca Ruigi and Clara Duffner, University of Helsinki, collecting Fucus outside the Archipelago Research Institute in Finland. 6 ! Ricardo Pereyra, University of Gothenburg, and Merli Pärnoja, University of Tartu, at the Kõiguste station on Saarema, Estonia, processing Fucus samples. ! ' ! Trackers to simulate the dispersal of detached Fucus plants were deployed along the Swedish and Finnish coastline under the supervision of Hanna Corell, University of Gothenburg. ! ! ( .
Load more

Recommended publications
  • To Down Load Appendix 1
    APPENDIX 1 Chapter 1 Pictures of dominant species ................................................................................................................................. 2 Species inventory of micro-invertebrate species found ....................................................................................... 16 Bathymetry Map of Pleasant Bay ........................................................................................................................ 18 Eelgrass Locations in Pleasant Bay ..................................................................................................................... 19 Sidescan Map of Pleasant Bay ............................................................................................................................. 20 Chapter 2 Species inventory of macro-invertebrate and fish species by gear type .............................................................. 21 Chapter 3 Prey otoliths and hard parts recovered during seal scat processing ..................................................................... 24 1 Pictures of dominant species Disclaimer: biological samples were treated with ethanol and Rose Bengal in the laboratory to preserve the samples. Rose Bengal is a stain commonly used in microscopy and stains cell tissue a bright pink. This is useful in the visual detection of microscopic animals in sediment samples. An overwhelming majority of micro invertebrate species do not have common names. The common names used here are listed in Pollock’s “A Practical Guide
    [Show full text]
  • Hepatopancreatic Endosymbionts in Coastal Isopods (Crustacea: Isopoda)
    Marine Biology 2001) 138: 955±963 Ó Springer-Verlag 2001 M. Zimmer á J. P. Danko á S. C. Pennings A. R. Danford á A. Ziegler á R. F. Uglow á T. H. Carefoot Hepatopancreatic endosymbionts in coastal isopods Crustacea: Isopoda), and their contribution to digestion Received: 28 August 2000 / Accepted: 8 December 2000 Abstract Three isopod species Crustacea: Isopoda), phenolic compounds was most developed in one of the commonly found in the intertidal and supratidal zones more marine species, suggesting that this trait may have of the North American Paci®c coast, were studied with evolved independently in isopod species that consume a respect to symbiotic microbiota in their midgut glands phenolic-rich diet, whether in marine habitats or on hepatopancreas). Ligia pallasii Oniscidea: Ligiidae) land. contained high numbers of microbialsymbionts in its hepatopancreatic caeca. Numbers of endosymbionts were strongly reduced by ingestion of antibiotics. By contrast, Introduction the hepatopancreas of Idotea wosnesenskii Valvifera: Idoteidae) and Gnorimosphaeroma oregonense Sphae- Endosymbionts are well known to play a key role in the romatidea: Sphaeromatidae) did not contain any mic- digestive processes of many terrestrialspecies summa- robiota. Results of feeding experiments suggest that rized in Martin 1983; Slaytor 1992; Breznak and Brune microbialendosymbionts contribute to digestive pro- 1994); however, their role in marine invertebrate species cesses in L. pallasii, the most terrestrialof the three is poorly understood. While studies have shown that gut isopods that we studied. The acquisition of digestion- microbiota exist in some marine invertebrates, know- enhancing endosymbionts may have been an important ledge of their nutritional role is scanty cf.
    [Show full text]
  • Synidotea Laevidorsalis Potential in RI COASTAL WATERS Asian Isopod Invader
    GUIDE TO MARINE INVADERS Synidotea laevidorsalis Potential IN RI COASTAL WATERS Asian isopod Invader PHYSICAL DESCRIPTION • Small, flattened (from top to bottom), crustacean (Isopoda) • Body color mottled tan to brown • Body elongated, widest in middle (thorax), with females slightly wider than males • Blunt, concave tail (telson) • Can grow to 1.2 in (3 cm) in length eyes located on Synidotea laevidorsalis lateral surface (dorsal view, female) of head shown at 200% actual size SERTC / SCDNR SERTC Left: Dorsal view of female Above: Dorsal view of male body widest at central thorax HABITAT PREFERENCE 7 pairs of • Found in shallow, subtidal waters attached to docks, appendages pilings, ropes, and other submerged structures • Prefers calm, protected waters; brackish water to full seawater 1 cm concave telson • Often clings to algae and hydroids with 2 blunt points © Rob Gough, DFBW 1 2 3 4 5 6 7 8 GUIDE TO MARINE INVADERS Synidotea laevidorsalis Potential IN RI COASTAL WATERS Asian isopod Invader INVASION STATUS & ECOLOGICAL CONCERNS Synidotea laevidorsalis is native to the Western Pacific Ocean and has been introduced to Europe, South America, Australia, and the United States, including San Francisco Bay, South Carolina, and the Delaware Bayshore of New Jersey. A marine isopod, S. laevidorsalis must be submerged in water to breathe. S. laevidorsalis grows to about 3 cm in length and can be found on docks and pilings among seaweed and hydroids. This isopod is classified as an omnivorous scavenger, eating both dead and living material, particularly hydroids. The camouflage pattern on its body allows it to blend in with its environment, and the tiny claws on each leg help it cling to surfaces.
    [Show full text]
  • Chapter 8 Benthic Assessment of Marine Areas of Particular
    Chapter 8 Benthic assessment of marine areas of particular ecological importance within the German Baltic Sea EEZ Michael L. Zettlera and Fritz Gosselckb a Baltic Sea Research Institute, Rostock b Institute for Applied Ecology, Broderstorf Abstract The Habitats Directive is one of the main legal tools of the European Union to preserve biodiversity by maintaining and restoring natural habitats, and establishing a network of protected sites (NATURA 2000). One point of interest is the characterisation of marine habitats to localise the areas that fulfil the protection targets. Of the habitats listed in Annex I of the Habitats Directive, mainly reefs and sandbanks are relevant in the case of German Baltic offshore waters. Along a strong salinity gradient (5 to 25 psu), four planned offshore Marine Protected Areas (MPAs) within the German Exclusive Economic Zone (EEZ) of the Baltic Sea were thoroughly investigated in this study. More than 250 locations were analysed using a combination of standard sampling methods, underwater video technique, and measurement of abiotic factors (salinity, oxygen, sediment parameters). The areas of interest were the Odra Bank (Oderbank), Adler Ground (Adlergrund), Kadet Trench (Kadetrinne), and Fehmarn Belt (Fehmarnbelt). The characteristic living communities (macrophytes, such as algae and sea grass, and macrozoobenthos such as worms, bivalves and crustaceans) for the different habitat types in these areas were characterised. Due to different salinity regimes, the benthic colonisation is different as well. In the Baltic Sea, with its decreasing salinity from west to east, the number of marine species declines, too. In the present study, altogether approximately 350 macrozoobenthic species and approximately 20 macrophytes were identified.
    [Show full text]
  • Invertebrate ID Guide
    11/13/13 1 This book is a compilation of identification resources for invertebrates found in stomach samples. By no means is it a complete list of all possible prey types. It is simply what has been found in past ChesMMAP and NEAMAP diet studies. A copy of this document is stored in both the ChesMMAP and NEAMAP lab network drives in a folder called ID Guides, along with other useful identification keys, articles, documents, and photos. If you want to see a larger version of any of the images in this document you can simply open the file and zoom in on the picture, or you can open the original file for the photo by navigating to the appropriate subfolder within the Fisheries Gut Lab folder. Other useful links for identification: Isopods http://www.19thcenturyscience.org/HMSC/HMSC-Reports/Zool-33/htm/doc.html http://www.19thcenturyscience.org/HMSC/HMSC-Reports/Zool-48/htm/doc.html Polychaetes http://web.vims.edu/bio/benthic/polychaete.html http://www.19thcenturyscience.org/HMSC/HMSC-Reports/Zool-34/htm/doc.html Cephalopods http://www.19thcenturyscience.org/HMSC/HMSC-Reports/Zool-44/htm/doc.html Amphipods http://www.19thcenturyscience.org/HMSC/HMSC-Reports/Zool-67/htm/doc.html Molluscs http://www.oceanica.cofc.edu/shellguide/ http://www.jaxshells.org/slife4.htm Bivalves http://www.jaxshells.org/atlanticb.htm Gastropods http://www.jaxshells.org/atlantic.htm Crustaceans http://www.jaxshells.org/slifex26.htm Echinoderms http://www.jaxshells.org/eich26.htm 2 PROTOZOA (FORAMINIFERA) ................................................................................................................................ 4 PORIFERA (SPONGES) ............................................................................................................................................... 4 CNIDARIA (JELLYFISHES, HYDROIDS, SEA ANEMONES) ............................................................................... 4 CTENOPHORA (COMB JELLIES)............................................................................................................................
    [Show full text]
  • The Book of the Sea the Realms of the Baltic Sea
    The Book of the Sea The realms of the Baltic Sea BALTIC ENVIRONMENTAL FORUM 1 THE REALMS OF THE BALTIC SEA 4 THE BOOK OF THE SEA 5 THE REALMS OF THE BALTIC SEA The Book of the Sea. The realms of the Baltic Sea 2 THE BOOK OF THE SEA 3 THE REALMS OF THE BALTIC SEA The Book of the Sea The realms of the Baltic Sea Gulf of Bothnia Åland Islands Helsinki Oslo Gulf of Finland A compilation by Žymantas Morkvėnas and Darius Daunys Stockholm Tallinn Hiiumaa Skagerrak Saaremaa Gulf of Riga Gotland Kattegat Öland Riga Copenhagen Baltic Sea Klaipėda Bornholm Bay of Gdańsk Rügen Baltic Environmental Forum 2015 2 THE BOOK OF THE SEA 3 THE REALMS OF THE BALTIC SEA Table of Contents Published in the framework of the Project partners: Authors of compilation Žymantas Morkvėnas and Darius Daunys 7 Preface 54 Brown shrimp project „Inventory of marine species Marine Science and Technology 54 Relict amphipod Texts provided by Darius Daunys, Žymantas Morkvėnas, Mindaugas Dagys, 9 Ecosystem of the Baltic Sea and habitats for development of Centre (MarsTec) at Klaipėda 55 Relict isopod crustacean Linas Ložys, Jūratė Lesutienė, Albertas Bitinas, Martynas Bučas, 11 Geological development Natura 2000 network in the offshore University, 57 Small sandeel Loreta Kelpšaitė-Rimkienė, Dalia Čebatariūnaitė, Nerijus Žitkevičius, of the Baltic Sea waters of Lithuania (DENOFLIT)“ Institute of Ecology of the Nature 58 Turbot Greta Gyraitė, Arūnas Grušas, Erlandas Paplauskis, Radvilė Jankevičienė, 14 The coasts of the Baltic Sea (LIFE09 NAT/LT/000234), Research Centre, 59 European flounder Rita Norvaišaitė 18 Water balance financed by the European Union The Fisheries Service under the 60 Velvet scoter 21 Salinity LIFE+ programme, the Republic Ministry of Agriculture of the Illustrations by Saulius Karalius 60 Common scoter 24 Food chain of Lithuania and project partners.
    [Show full text]
  • Biological Valorisation of the Southern Baltic Sea (Polish Exclusive
    Biological valorisation OCEANOLOGIA, 51 (3), 2009. pp. 415–435. of the southern Baltic C 2009, by Institute of Sea (Polish Exclusive Oceanology PAS. Economic Zone)* KEYWORDS Valuation Biodiversity Baltic Marine habitats JanMarcinWęsławski1,∗ Jan Warzocha2 Józef Wiktor1 Jacek Urbański3 Katarzyna Bradtke3 Lucyna Kryla3 Agnieszka Tatarek1 Lech Kotwicki1 Joanna Piwowarczyk1 1 Institute of Oceanology, Polish Academy of Sciences, Powstańców Warszawy 55, PL–81–712 Sopot, Poland; e-mail: [email protected] ∗corresponding author 2 Sea Fisheries Institute, Kołłątaja 1, PL–81–332 Gdynia, Poland 3 Institute of Oceanography, University of Gdańsk, al. Marszałka Piłsudskiego 46, PL–81–378 Gdynia, Poland Received 24 March 2009, revised 8 June 2009, accepted 15 June 2009. Abstract A biological valuation system to assess the value associated with ecosystem stability and richness (and not that from the point of view of users) is proposed to provide * This project was supported by the Norwegian Financial Mechanism Grant 2007–08 (Habitat mapping in Polish Marine Areas with special reference to Natura 2000 areas). The complete text of the paper is available at http://www.iopan.gda.pl/oceanologia/ 416 J. M. Węsławski, J. Warzocha, J. Wiktor et al. scientific decision support for marine protected areas and marine spatial planning. The system is based on the assessment of individual species and habitat/species assemblages. An extensive set of recently collected (2007–08) and archival (1970 –2000) data on the occurrence of marine benthos was analysed for the Polish Marine Areas. Based on matching data sets of sediments, the euphotic zone, temperature and salinity, as well as fetch and sea current values, a GIS model was used to visualise the results; a map indicates the two areas which are considered to be biologically the most valuable (Puck Bay and the stony shallows of the central coast).
    [Show full text]
  • BONUS BAMBI Final Report
    BONUS BAMBI PROJECT (1.1.2014 to 31.12.2017) The final publishable summary report February 28th 2018 Illustration: J Lokrantz/Azote Project website: www.bambi.gu.se BONUS BAMBI project has received funding from BONUS (Art 185), funded jointly by the EU and the national funding agencies Swedish research agency Formas, Estonian Research Council ETAg, German Forschungszentrum Jülich Beteiligungsgesellschaft, and the Academy of Finland. Project outline of goals and results envisaged at the beginning of the project cycle A rapidly warming Baltic Sea that will also be impacted by lower salinities than today will put a heavy pressure on all species with marine origin currently living in the Baltic Sea. Already today, the Baltic Sea is extremely species poor with roughly only 10 percent of the number of species found in the North Sea. The overall goal of BONUS BAMBI was to generate new knowledge on genetic biodiversity of Baltic Sea populations, in order to understand how the ongoing changes in temperature and salinity will affect key marine species of the Baltic Sea. The project also aimed to assess the degree of management that is currently directed towards genetic diversity. In addition, the goal was to communicate new insights on genetic biodiversity to Baltic Sea managers and policy-makers. Work carried out in the project A main issue has been to identify the population structures of four key-species; bladder wrack Fucus vesiculosus, narrow wrack Fucus radicans, Baltic isopod Idotea balthica and three-spined stickleback Gasterosteus aculeatus. For three of the species this involved the development of new powerful genetic markers, so called RAD markers.
    [Show full text]
  • The Terrestrial Isopod Microbiome: an All-In-One Toolbox for Animal–Microbe Interactions of Ecological Relevance
    The Terrestrial Isopod Microbiome: An All-in-One Toolbox for Animal–Microbe Interactions of Ecological Relevance The Harvard community has made this article openly available. Please share how this access benefits you. Your story matters Citation Bouchon, Didier, Martin Zimmer, and Jessica Dittmer. 2016. “The Terrestrial Isopod Microbiome: An All-in-One Toolbox for Animal–Microbe Interactions of Ecological Relevance.” Frontiers in Microbiology 7 (1): 1472. doi:10.3389/fmicb.2016.01472. http:// dx.doi.org/10.3389/fmicb.2016.01472. Published Version doi:10.3389/fmicb.2016.01472 Citable link http://nrs.harvard.edu/urn-3:HUL.InstRepos:29408382 Terms of Use This article was downloaded from Harvard University’s DASH repository, and is made available under the terms and conditions applicable to Other Posted Material, as set forth at http:// nrs.harvard.edu/urn-3:HUL.InstRepos:dash.current.terms-of- use#LAA fmicb-07-01472 September 21, 2016 Time: 14:13 # 1 REVIEW published: 23 September 2016 doi: 10.3389/fmicb.2016.01472 The Terrestrial Isopod Microbiome: An All-in-One Toolbox for Animal–Microbe Interactions of Ecological Relevance Didier Bouchon1*, Martin Zimmer2 and Jessica Dittmer3 1 UMR CNRS 7267, Ecologie et Biologie des Interactions, Université de Poitiers, Poitiers, France, 2 Leibniz Center for Tropical Marine Ecology, Bremen, Germany, 3 Rowland Institute at Harvard, Harvard University, Cambridge, MA, USA Bacterial symbionts represent essential drivers of arthropod ecology and evolution, influencing host traits such as nutrition, reproduction, immunity, and speciation. However, the majority of work on arthropod microbiota has been conducted in insects and more studies in non-model species across different ecological niches will be needed to complete our understanding of host–microbiota interactions.
    [Show full text]
  • The Sound Biodiversity, Threats, and Transboundary Protection.Indd
    2017 The Sound: Biodiversity, threats, and transboundary protection 2 Windmills near Copenhagen. Denmark. © OCEANA/ Carlos Minguell Credits & Acknowledgments Authors: Allison L. Perry, Hanna Paulomäki, Tore Hejl Holm Hansen, Jorge Blanco Editor: Marta Madina Editorial Assistant: Ángeles Sáez Design and layout: NEO Estudio Gráfico, S.L. Cover photo: Oceana diver under a wind generator, swimming over algae and mussels. Lillgrund, south of Øresund Bridge, Sweden. © OCEANA/ Carlos Suárez Recommended citation: Perry, A.L, Paulomäki, H., Holm-Hansen, T.H., and Blanco, J. 2017. The Sound: Biodiversity, threats, and transboundary protection. Oceana, Madrid: 72 pp. Reproduction of the information gathered in this report is permitted as long as © OCEANA is cited as the source. Acknowledgements This project was made possible thanks to the generous support of Svenska PostkodStiftelsen (the Swedish Postcode Foundation). We gratefully acknowledge the following people who advised us, provided data, participated in the research expedition, attended the October 2016 stakeholder gathering, or provided other support during the project: Lars Anker Angantyr (The Sound Water Cooperation), Kjell Andersson, Karin Bergendal (Swedish Society for Nature Conservation, Malmö/Skåne), Annelie Brand (Environment Department, Helsingborg municipality), Henrik Carl (Fiskeatlas), Magnus Danbolt, Magnus Eckeskog (Greenpeace), Søren Jacobsen (Association for Sensible Coastal Fishing), Jens Peder Jeppesen (The Sound Aquarium), Sven Bertil Johnson (The Sound Fund), Markus Lundgren
    [Show full text]
  • Behavioural and Metabolic Adaptations of Marine Isopods to the Rafting Life Style
    Marine Biology (2006) 149: 821–828 DOI 10.1007/s00227-006-0257-9 RESEARCH ARTICLE Lars Gutow Æ Julia Strahl Æ Christian Wiencke Heinz-Dieter Franke Æ Reinhard Saborowski Behavioural and metabolic adaptations of marine isopods to the rafting life style Received: 20 July 2005 / Accepted: 16 January 2006 / Published online: 7 February 2006 Ó Springer-Verlag 2006 Abstract Rafting on floating objects is a common dis- Introduction persal mechanism for many marine invertebrates. In order to identify adaptations to the rafting life style, we Seven isopod species of the genus Idotea form resident compared behavioural and metabolic characteristics of populations around the island of Helgoland (German two isopods, the obligate rafter Idotea metallica and the Bight, North Sea; Franke et al. 1999). They are dis- facultative rafter Idotea baltica. In laboratory experi- tributed benthically along the coast from the supratidal ments, I. metallica showed low locomotive activity and a down to subtidal habitats (Naylor 1972). The distribu- tight association to the substratum. Idotea baltica,in tion of Idotea baltica and Idotea emarginata is primarily contrast, was more active with more frequent excursions the result of interspecific competition and subsequent in the surrounding water column. Oxygen consumption habitat segregation (Franke and Janke 1998). Although rates were similar in both species. Idotea metallica fed on they prefer benthic habitats, all species also raft on zooplankton making this species widely independent of floating objects at the sea surface; most of them, how- autochthonous food resources of the raft. Feeding rates ever, only sporadically. Only I. baltica is abundant on and digestive enzyme activities were low in I.
    [Show full text]
  • Mapping Present and Future Potential Distribution Patterns for A
    Journal of Biogeography (J. Biogeogr.) (2014) ORIGINAL Mapping present and future potential ARTICLE distribution patterns for a meso-grazer guild in the Baltic Sea Sonja Leidenberger1*, Renato De Giovanni2, Robert Kulawik3, Alan R. Williams4 and Sarah J. Bourlat5 1Department of Biology and Environmental ABSTRACT Sciences, Kristineberg, University of Aim The Baltic Sea is one of the world’s largest semi-enclosed brackish water Gothenburg, Kristineberg 566 SE-451 78 2 bodies characterized by many special features, including endemic species that Fiskeb€ackskil, Sweden, Centro de Refer^encia em Informacß~ao Ambiental, CRIA, Brazil, may be particularly threatened by climate change. We mapped potential distri- 3Fraunhofer IAIS Knowledge Discovery, bution patterns under present and future conditions for a community with Schloss Birlinghoven, 53754 Sankt Augustin, three trophic levels. We analysed climate-induced changes in the species’ distri- Germany, 4School of Computer Science, bution patterns and examined possible consequences for the chosen food web. University of Manchester, Oxford Road, Location Baltic Sea and northern Europe. Manchester M13 9PL, UK, 5Department of Biology and Environmental Sciences, Methods We developed two open-source workflow-based analytical tools: one University of Gothenburg, SE-405 30 G€oteborg, for ecological niche modelling and another for raster layer comparison to com- Sweden pute the extent and intensity of change in species’ potential distributions. Indi- vidual ecological niche models were generated under present conditions and then projected into a future climate change scenario (2050) for a food web consisting of a guild of meso-grazers (Idotea spp.), their host algae (Fucus vesi- culosus and Fucus radicans) and their fish predator (Gasterosteus aculeatus).
    [Show full text]