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5. Techniques for cetacean–habitat modeling

Author

Redfern, J. V., Ferguson, M. C., Becker, E. A., Hyrenbach, K. D., Good, C., Barlow, J., Kaschner, K., Baumgartner, M. F., Forney, K. A., Ballance, L. T., Fauchald, P., Halpin, P., Hamazaki, T., Pershing, A. J., Qian, S. S., Read, A., Reilly, S. B., Torres, L., and Werner, F.

Published
2006

7. Large marine protected areas represent biodiversity now and under climate change

Author

Davies, T. E., Maxwell, S. M., Kaschner, K., Garilao, Cristina, Ban, N. C., Davies, T. E., Maxwell, S. M., Kaschner, K., Garilao, Cristina, and Ban, N. C.

Abstract

Large marine protected areas (>30,000 km2) have a high profile in marine conservation, yet their contribution to conservation is contested. Assessing the overlap of large marine protected areas with 14,172 species, we found large marine protected areas cover 4.4% of the ocean and at least some portion of the range of 83.3% of the species assessed. Of all species within large marine protected areas, 26.9% had at least 10% of their range represented, and this was projected to increase to 40.1% in 2100. Cumulative impacts were significantly higher within large marine protected areas than outside, refuting the critique that they only occur in pristine areas. We recommend future large marine protected areas be sited based on systematic conservation planning practices where possible and include areas beyond national jurisdiction, and provide five key recommendations to improve the long-term representation of all species to meet critical global policy goals (e.g., Convention on Biological Diversity's Aichi Targets)

Published
2017
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8. Automatic test case generation for interacting services

Author

Kaschner, K., Lohmann, N., Feuerlicht, G., and Lamersdorf, W.

Subjects
Service (business), Test case, Computer science, Integration testing, Distributed computing, White-box testing, Test Management Approach, Software system, Task (project management), Test (assessment)
Abstract

Service-oriented architectures propose loosely coupled interacting services as building blocks for distributed applications. Since distributed services differ from traditional monolithic software systems, novel testing methods are required. Based on the specification of a service, we introduce an approach to automatically generate test cases for black-box testing to check for conformance between the specification and the implementation of a service whose internal behavior might be confidential. Due to the interacting nature of services this is a nontrivial task.

Published
2009
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12. Does my service have unspecified behavior?

Author

Kaschner, K., Lohmann, N., and Kopp, O.

Abstract

Services are loosely coupled interacting software components. Since two or more services are usually composed to one software system, the behavior of an implemented service should not differ to its specification. Therefore we propose an approach to test, if the implementation contains unspecified behavior. Due to the interacting nature of services this is a nontrivial task.

Published
2009

13. Techniques for cetacean–habitat modeling

Author

Becker, E. A., Halpin, P., Baumgartner, M. F., Werner, F., Forney, K. A., Pershing, A. J., Barlow, J., Read, A., Torres, L., Fauchald, P., Ferguson, M. C., Redfern, J. V., Hyrenbach, K. D., Kaschner, K., Ballance, L. T., Reilly, S. B., Hamazaki, T., Qian, S. S., and Good, C.

Abstract

Cetacean-habitat modeling, although still in the early stages of development, represents a potentially powerful tool for predicting cetacean distributions and understanding the ecological processes determining these distributions. Marine ecosystems vary temporally on diel to decadal scales and spatially on scales from several meters to 1000s of kilometers. Many cetacean species are wide-ranging and respond to this variability by changes in distribution patterns. Cetacean-habitat models have already been used to incorporate this variability into management applications, including improvement of abundance estimates, development of marine protected areas, and understanding cetacean-fisheries interactions. We present a review of the development of cetacean-habitat models, organized according to the primary steps involved in the modeling process. Topics covered include purposes for which cetacean-habitat models are developed, scale issues in marine ecosystems, cetacean and habitat data collection, descriptive and statistical modeling techniques, model selection, and model evaluation. To date, descriptive statistical techniques have been used to explore cetacean-habitat relationships for selected species in specific areas; the numbers of species and geographic areas examined using computationally intensive statistic modeling techniques are considerably less, and the development of models to test specific hypotheses about the ecological processes determining cetacean distributions has just begun. Future directions in cetacean-habitat modeling span a wide range of possibilities, from development of basic modeling techniques to addressing important ecological questions.

Published
2006
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14. Ancient DNA reveals that bowhead whale lineages survived Late Pleistocene climate change and habitat shifts

Author

Foote, A., Kaschner, K., Schultze, S., Garilao, C., Ho, S., Post, K., Higham, T., Stokowska, C., Van der Es, H., Embling, C., Gregersen, K., Johansson, F., Willerslev, E., Gilbert, Thomas, Foote, A., Kaschner, K., Schultze, S., Garilao, C., Ho, S., Post, K., Higham, T., Stokowska, C., Van der Es, H., Embling, C., Gregersen, K., Johansson, F., Willerslev, E., and Gilbert, Thomas

Abstract

The climatic changes of the glacial cycles are thought to have been a major driver ofpopulation declines and species extinctions. However, studies to date have focused onterrestrial fauna and there is little understanding of how marine species responded to pastclimate change. Here we show that a true Arctic species, the bowhead whale (Balaenamysticetus), shifted its range and tracked its core suitable habitat northwards during the rapidclimate change of the Pleistocene–Holocene transition. Late Pleistocene lineages survivedinto the Holocene and effective female population size increased rapidly, concurrent with athreefold increase in core suitable habitat. This study highlights that responses to climatechange are likely to be species specific and difficult to predict. We estimate that the coresuitable habitat of bowhead whales will be almost halved by the end of this century,potentially influencing future population dynamics.

Published
2013

15. Using 'Aquamaps' for representing species distribution in Regional Seas

Author

Christensen, V., Lai, S., Palomares, M. L. D., Zeller, D., Pauly, D., Kaschner, K., Ready, J. S., Agbayani, E., Kesner-Reyes, K., Rius-Barile, J., Eastwood, P. D., South, A. B., Kullander, S. O., Rees, T., Watson, R., Froese, Rainer, Christensen, V., Lai, S., Palomares, M. L. D., Zeller, D., Pauly, D., Kaschner, K., Ready, J. S., Agbayani, E., Kesner-Reyes, K., Rius-Barile, J., Eastwood, P. D., South, A. B., Kullander, S. O., Rees, T., Watson, R., and Froese, Rainer

Published
2011

16. Techniques for cetacean–habitat modeling

Author

Redfern, J. V., Ferguson, M. C., Becker, E. A., Hyrenbach, K. D., Good, Caroline P., Barlow, Jay, Kaschner, K., Baumgartner, Mark F., Forney, K. A., Ballance, L. T., Fauchald, P., Halpin, Patrick N., Hamazaki, T., Pershing, Andrew J., Qian, Song S., Read, Andrew J., Reilly, S. B., Torres, Leigh, Werner, Francisco E., Redfern, J. V., Ferguson, M. C., Becker, E. A., Hyrenbach, K. D., Good, Caroline P., Barlow, Jay, Kaschner, K., Baumgartner, Mark F., Forney, K. A., Ballance, L. T., Fauchald, P., Halpin, Patrick N., Hamazaki, T., Pershing, Andrew J., Qian, Song S., Read, Andrew J., Reilly, S. B., Torres, Leigh, and Werner, Francisco E.

Abstract

Author Posting. © Inter-Research, 2006. This article is posted here by permission of Inter-Research for personal use, not for redistribution. The definitive version was published in Marine Ecology Progress Series 310 (2006): 271-295, doi:10.3354/meps310271., Cetacean–habitat modeling, although still in the early stages of development, represents a potentially powerful tool for predicting cetacean distributions and understanding the ecological processes determining these distributions. Marine ecosystems vary temporally on diel to decadal scales and spatially on scales from several meters to 1000s of kilometers. Many cetacean species are wide-ranging and respond to this variability by changes in distribution patterns. Cetacean–habitat models have already been used to incorporate this variability into management applications, including improvement of abundance estimates, development of marine protected areas, and understanding cetacean–fisheries interactions. We present a review of the development of cetacean–habitat models, organized according to the primary steps involved in the modeling process. Topics covered include purposes for which cetacean–habitat models are developed, scale issues in marine ecosystems, cetacean and habitat data collection, descriptive and statistical modeling techniques, model selection, and model evaluation. To date, descriptive statistical techniques have been used to explore cetacean–habitat relationships for selected species in specific areas; the numbers of species and geographic areas examined using computationally intensive statistic modeling techniques are considerably less, and the development of models to test specific hypotheses about the ecological processes determining cetacean distributions has just begun. Future directions in cetacean–habitat modeling span a wide range of possibilities, from development of basic modeling techniques to addressing important ecological questions., Funding from the U.S. Navy and the Strategic Environmental Research and Development Program (SERDP) supported this research under Projects CS-1390 and CS-1391.

Published
2011

17. Modelling harbour porpoise seasonal density as a function of the German Bight environment: implications for management

Author

Gilles, A., Adler, S., Kaschner, K., Scheidat, M., Siebert, U., Gilles, A., Adler, S., Kaschner, K., Scheidat, M., and Siebert, U.

Abstract

A classical user–environment conflict could arise between the recent expansion plans of offshore wind power in European waters and the protection of the harbour porpoise Phocoena phocoena, an important top predator and indicator species in the North Sea. There is a growing demand for predictive models of porpoise distribution to assess the extent of potential conflicts and to support conservation and management plans. Here, we used a range of oceanographic parameters and generalised additive models to predict harbour porpoise density and to investigate seasonal shifts in porpoise distribution in relation to several static and dynamic predictors. Sightings were collected during dedicated line-transect aerial surveys conducted year-round between 2002 and 2005. Over the 4 yr, survey effort amounted to 38720 km, during which 3887 harbour porpoises were sighted. Porpoises aggregated in distinct hot spots within their seasonal range, but the importance of key habitat descriptors varied between seasons. Predictors explaining most of the variance were the hydrographical parameter ‘residual current’ and proxies for primary production and fronts (chlorophyll and nutrients) as well as the interaction ‘distance to coast/water depth’. Porpoises preferred areas with stronger currents and concentrated in areas where fronts are likely. Internal cross-validation indicated that all models were highly robust. In addition, we successfully externally validated our summer model using an independent data set, which allowed us to extrapolate our predictions to a more regional scale. Our models improve the understanding of determinants of harbour porpoise habitat in the North Sea as a whole and inform management frameworks to determine safe limits of anthropogenic impacts

Published
2011

18. Database-driven models of the world's Large Marine Ecosystems

Author

Christensen, V., Walters, C. J., Ahrens, R., Alder, J., Buszowski, J., Christensen, L. B., Cheung, W. W. L., Dunne, J., Froese, Rainer, Karpouzi, V., Kaschner, K., Kearney, K., Lai, S., Lam, V., Palomares, M. L. D., Peters-Mason, A., Piroddi, C., Sarmiento, J.L., Steenbeek, J., Sumaila, R., Watson, R., Zeller, D., Pauly, D., Christensen, V., Walters, C. J., Ahrens, R., Alder, J., Buszowski, J., Christensen, L. B., Cheung, W. W. L., Dunne, J., Froese, Rainer, Karpouzi, V., Kaschner, K., Kearney, K., Lai, S., Lam, V., Palomares, M. L. D., Peters-Mason, A., Piroddi, C., Sarmiento, J.L., Steenbeek, J., Sumaila, R., Watson, R., Zeller, D., and Pauly, D.

Published
2009
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22. Techniques for cetacean–habitat modeling

Author

Redfern, JV, primary, Ferguson, MC, additional, Becker, EA, additional, Hyrenbach, KD, additional, Good, C, additional, Barlow, J, additional, Kaschner, K, additional, Baumgartner, MF, additional, Forney, KA, additional, Ballance, LT, additional, Fauchald, P, additional, Halpin, P, additional, Hamazaki, T, additional, Pershing, AJ, additional, Qian, SS, additional, Read, A, additional, Reilly, SB, additional, Torres, L, additional, and Werne, F, additional

Published
2006
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24. Blueprints of Effective Biodiversity and Conservation Knowledge Products That Support Marine Policy

Author

Weatherdon, LV, Appeltans, W, Bowles-Newark, N, Brooks, TM, Davis, FE, Despot-Belmonte, K, Fletcher, S, Garilao, C, Hilton-Taylor, C, Hirsch, T, Juffe-Bignoli, D, Kaschner, K, Kingston, N, Malsch, K, Regan, EC, Kesner-Reyes, K, Rose, DC, Wetzel, FT, Wilkinson, T, and Martin, CS

Subjects
knowledge products, 13. Climate action, marine policy, knowledge exchange, evidence-based conservation, 14. Life underwater, 15. Life on land, biodiversity informatics, science-policy interface
Abstract

Biodiversity and conservation data are generally costly to collect, particularly in the marine realm. Hence, data collected for a given—often scientific—purpose are occasionally contributed toward secondary needs, such as policy implementation or other types of decision-making. However, while the quality and accessibility of marine biodiversity and conservation data have improved over the past decade, the ways in which these data can be used to develop and implement relevant management and conservation measures and actions are not always explicit. For this reason, there are a number of scientifically-sound datasets that are not used systematically to inform policy and decisions. Transforming these marine biodiversity and conservation datasets into knowledge products that convey the information required by policy- and decision-makers is an important step in strengthening knowledge exchange across the science-policy interface. Here, we identify seven characteristics of a selection of online biodiversity and conservation knowledge products that contribute to their ability to support policy- and decision-making in the marine realm (as measured by e.g., mentions in policy resolutions/decisions, or use for reporting under selected policy instruments; use in high-level screening for areas of biodiversity importance). These characteristics include: a clear policy mandate; established networks of collaborators; iterative co-design of a user-friendly interface; standardized, comprehensive and documented methods with quality assurance; consistent capacity and succession planning; accessible data and value-added products that are fit-for-purpose; and metrics of use collated and reported. The outcomes of this review are intended to: (a) support data creators/owners/providers in designing and curating biodiversity and conservation knowledge products that have greater influence, and hence impact, in policy- and decision-making, and (b) provide recommendations for how decision- and policy-makers can support the development, implementation, and sustainability of robust biodiversity and conservation knowledge products through the framing of marine policy and decision-making frameworks.

25. Advancing global ecological modelling capabilities to simulate future trajectories of change in marine ecosystems

Author

Coll, Marta, Steenbeek, Jeroen, Pennino, María Gracia, Buszowski, J., Kaschner, K., Lotze, H., Rousseau, Y., Tittensor, D.P., Walters, C., Watson, R.A., Christensen, V., Coll, Marta, Steenbeek, Jeroen, Pennino, María Gracia, Buszowski, J., Kaschner, K., Lotze, H., Rousseau, Y., Tittensor, D.P., Walters, C., Watson, R.A., and Christensen, V.

Abstract

Considerable effort is being deployed to predict the impacts of climate change and anthropogenic activities on the ocean's biophysical environment, biodiversity, and natural resources to better understand how marine ecosystems and provided services to humans are likely to change and explore alternative pathways and options. We present an updated version of EcoOcean (v2), a spatial-temporal ecosystem modeling complex of the global ocean that spans food-web dynamics from primary producers to top predators. Advancements include an enhanced ability to reproduce spatial-temporal ecosystem dynamics by linking species productivity, distributions, and trophic interactions to the impacts of climate change and worldwide fisheries. The updated modeling platform is used to simulate past and future scenarios of change, where we quantify the impacts of alternative configurations of the ecological model, responses to climate-change scenarios, and the additional impacts of fishing. Climate-change scenarios are obtained from two Earth-System Models (ESMs, GFDL-ESM2M, and IPSL-CMA5-LR) and two contrasting emission pathways (RCPs 2.6 and 8.5) for historical (1950–2005) and future (2006–2100) periods. Standardized ecological indicators and biomasses of selected species groups are used to compare simulations. Results show how future ecological trajectories are sensitive to alternative configurations of EcoOcean, and yield moderate differences when looking at ecological indicators and larger differences for biomasses of species groups. Ecological trajectories are also sensitive to environmental drivers from alternative ESM outputs and RCPs, and show spatial variability and more severe changes when IPSL and RCP 8.5 are used. Under a non-fishing configuration, larger organisms show decreasing trends, while smaller organisms show mixed or increasing results. Fishing intensifies the negative effects predicted by climate change, again stronger under IPSL and RCP 8.5, which results in stronger

26. Cumulative human impacts on global marine fauna highlight risk to biological and functional diversity.

Author

O'Hara CC, Frazier M, Valle M, Butt N, Kaschner K, Klein C, and Halpern BS

Subjects
Animals, Humans, Climate Change, Ecosystem, Human Activities, Oceans and Seas, Anthropogenic Effects, Biodiversity, Aquatic Organisms physiology, Conservation of Natural Resources
Abstract

Anthropogenic stressors to marine ecosystems from climate change and human activities increase extinction risk of species, disrupt ecosystem integrity, and threaten important ecosystem services. Addressing these stressors requires understanding where and to what extent they are impacting marine biological and functional diversity. We model cumulative risk of human impact upon 21,159 marine animal species by combining information on species-level vulnerability and spatial exposure to a range of anthropogenic stressors. We apply this species-level assessment of human impacts to examine patterns of species-stressor interactions within taxonomic groups. We then spatially map impacts across the global ocean, identifying locations where climate-driven impacts overlap with fishing, shipping, and land-based stressors to help inform conservation needs and opportunities. Comparing species-level modeled impacts to those based on marine habitats that represent important marine ecosystems, we find that even relatively untouched habitats may still be home to species at elevated risk, and that many species-rich coastal regions may be at greater risk than indicated from habitat-based methods alone. Finally, we incorporate a trait-based metric of functional diversity to identify where impacts to functionally unique species might pose greater risk to community structure and ecosystem integrity. These complementary lenses of species, function, and habitat provide a richer understanding of threats to marine biodiversity to help inform efforts to meet conservation targets and ensure sustainability of nature's contributions to people., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 O’Hara et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published
2024
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27. Temporal dynamics of climate change exposure and opportunities for global marine biodiversity.

Author

Meyer AS, Pigot AL, Merow C, Kaschner K, Garilao C, Kesner-Reyes K, and Trisos CH

Subjects
Animals, Ecosystem, Oceans and Seas, Biodiversity, Climate Change, Temperature, Aquatic Organisms physiology
Abstract

Climate change is exposing marine species to unsuitable temperatures while also creating new thermally suitable habitats of varying persistence. However, understanding how these different dynamics will unfold over time remains limited. We use yearly sea surface temperature projections to estimate temporal dynamics of thermal exposure (when temperature exceeds realised species' thermal limits) and opportunity (when temperature at a previously unsuitable site becomes suitable) for 21,696 marine species globally until 2100. Thermal opportunities are projected to arise earlier and accumulate gradually, especially in temperate and polar regions. Thermal exposure increases later and occurs more abruptly, mainly in the tropics. Assemblages tend to show either high exposure or high opportunity, but seldom both. Strong emissions reductions reduce exposure around 100-fold whereas reductions in opportunities are halved. Globally, opportunities are projected to emerge faster than exposure until mid-century when exposure increases more rapidly under a high emissions scenario. Moreover, across emissions and dispersal scenarios, 76%-97% of opportunities are projected to persist until 2100. These results indicate thermal opportunities could be a major source of marine biodiversity change, especially in the near- and mid-term. Our work provides a framework for predicting where and when thermal changes will occur to guide monitoring efforts., (© 2024. The Author(s).)

Published
2024
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29. Climate change disrupts core habitats of marine species.

Author

Hodapp D, Roca IT, Fiorentino D, Garilao C, Kaschner K, Kesner-Reyes K, Schneider B, Segschneider J, Kocsis ÁT, Kiessling W, Brey T, and Froese R

Subjects
Biodiversity, Food Chain, Ecosystem, Climate Change
Abstract

Driven by climate change, marine biodiversity is undergoing a phase of rapid change that has proven to be even faster than changes observed in terrestrial ecosystems. Understanding how these changes in species composition will affect future marine life is crucial for conservation management, especially due to increasing demands for marine natural resources. Here, we analyse predictions of a multiparameter habitat suitability model covering the global projected ranges of >33,500 marine species from climate model projections under three CO 2 emission scenarios (RCP2.6, RCP4.5, RCP8.5) up to the year 2100. Our results show that the core habitat area will decline for many species, resulting in a net loss of 50% of the core habitat area for almost half of all marine species in 2100 under the high-emission scenario RCP8.5. As an additional consequence of the continuing distributional reorganization of marine life, gaps around the equator will appear for 8% (RCP2.6), 24% (RCP4.5), and 88% (RCP8.5) of marine species with cross-equatorial ranges. For many more species, continuous distributional ranges will be disrupted, thus reducing effective population size. In addition, high invasion rates in higher latitudes and polar regions will lead to substantial changes in the ecosystem and food web structure, particularly regarding the introduction of new predators. Overall, our study highlights that the degree of spatial and structural reorganization of marine life with ensued consequences for ecosystem functionality and conservation efforts will critically depend on the realized greenhouse gas emission pathway., (© 2023 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published
2023
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30. A metric-based framework for climate-smart conservation planning.

Author

Buenafe KCV, Dunn DC, Everett JD, Brito-Morales I, Schoeman DS, Hanson JO, Dabalà A, Neubert S, Cannicci S, Kaschner K, and Richardson AJ

Subjects
Hydrogen-Ion Concentration, Biodiversity, Uncertainty, Climate Change, Ecosystem, Conservation of Natural Resources methods, Seawater
Abstract

Climate change is already having profound effects on biodiversity, but climate change adaptation has yet to be fully incorporated into area-based management tools used to conserve biodiversity, such as protected areas. One main obstacle is the lack of consensus regarding how impacts of climate change can be included in spatial conservation plans. We propose a climate-smart framework that prioritizes the protection of climate refugia-areas of low climate exposure and high biodiversity retention-using climate metrics. We explore four aspects of climate-smart conservation planning: (1) climate model ensembles; (2) multiple emission scenarios; (3) climate metrics; and (4) approaches to identifying climate refugia. We illustrate this framework in the Western Pacific Ocean, but it is equally applicable to terrestrial systems. We found that all aspects of climate-smart conservation planning considered affected the configuration of spatial plans. The choice of climate metrics and approaches to identifying refugia have large effects in the resulting climate-smart spatial plans, whereas the choice of climate models and emission scenarios have smaller effects. As the configuration of spatial plans depended on climate metrics used, a spatial plan based on a single measure of climate change (e.g., warming) will not necessarily be robust against other measures of climate change (e.g., ocean acidification). We therefore recommend using climate metrics most relevant for the biodiversity and region considered based on a single or multiple climate drivers. To include the uncertainty associated with different climate futures, we recommend using multiple climate models (i.e., an ensemble) and emission scenarios. Finally, we show that the approaches we used to identify climate refugia feature trade-offs between: (1) the degree to which they are climate-smart, and (2) their efficiency in meeting conservation targets. Hence, the choice of approach will depend on the relative value that stakeholders place on climate adaptation. By using this framework, protected areas can be designed with improved longevity and thus safeguard biodiversity against current and future climate change. We hope that the proposed climate-smart framework helps transition conservation planning toward climate-smart approaches., (© 2023 The Authors. Ecological Applications published by Wiley Periodicals LLC on behalf of The Ecological Society of America.)

Published
2023
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31. Reply to: Quantifying the carbon benefits of ending bottom trawling.

Author

Atwood TB, Sala E, Mayorga J, Bradley D, Cabral RB, Auber A, Cheung W, Ferretti F, Friedlander AM, Gaines SD, Garilao C, Goodell W, Halpern BS, Hinson A, Kaschner K, Kesner-Reyes K, Leprieur F, McGowan J, Morgan LE, Mouillot D, Palacios-Abrantes J, Possingham HP, Rechberger KD, Worm B, and Lubchenco J

Subjects
Ecosystem, Carbon, Fisheries
Published
2023
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32. A functional vulnerability framework for biodiversity conservation.

Author

Auber A, Waldock C, Maire A, Goberville E, Albouy C, Algar AC, McLean M, Brind'Amour A, Green AL, Tupper M, Vigliola L, Kaschner K, Kesner-Reyes K, Beger M, Tjiputra J, Toussaint A, Violle C, Mouquet N, Thuiller W, and Mouillot D

Subjects
Animals, Biodiversity, Fishes physiology, Mammals, Conservation of Natural Resources, Ecosystem
Abstract

Setting appropriate conservation strategies in a multi-threat world is a challenging goal, especially because of natural complexity and budget limitations that prevent effective management of all ecosystems. Safeguarding the most threatened ecosystems requires accurate and integrative quantification of their vulnerability and their functioning, particularly the potential loss of species trait diversity which imperils their functioning. However, the magnitude of threats and associated biological responses both have high uncertainties. Additionally, a major difficulty is the recurrent lack of reference conditions for a fair and operational measurement of vulnerability. Here, we present a functional vulnerability framework that incorporates uncertainty and reference conditions into a generalizable tool. Through in silico simulations of disturbances, our framework allows us to quantify the vulnerability of communities to a wide range of threats. We demonstrate the relevance and operationality of our framework, and its global, scalable and quantitative comparability, through three case studies on marine fishes and mammals. We show that functional vulnerability has marked geographic and temporal patterns. We underline contrasting contributions of species richness and functional redundancy to the level of vulnerability among case studies, indicating that our integrative assessment can also identify the drivers of vulnerability in a world where uncertainty is omnipresent., (© 2022. The Author(s).)

Published
2022
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33. 4D marine conservation networks: Combining 3D prioritization of present and future biodiversity with climatic refugia.

Author

Doxa A, Almpanidou V, Katsanevakis S, Queirós AM, Kaschner K, Garilao C, Kesner-Reyes K, and Mazaris AD

Subjects
Biodiversity, Climate Change, Conservation of Natural Resources methods, Mediterranean Sea, Ecosystem, Refugium
Abstract

Given the accelerating rate of biodiversity loss, the need to prioritize marine areas for protection represents a major conservation challenge. The three-dimensionality of marine life and ecosystems is an inherent element of complexity for setting spatial conservation plans. Yet, the confidence of any recommendation largely depends on shifting climate, which triggers a global redistribution of biodiversity, suggesting the inclusion of time as a fourth dimension. Here, we developed a depth-specific prioritization analysis to inform the design of protected areas, further including metrics of climate-driven changes in the ocean. Climate change was captured in this analysis by considering the projected future distribution of >2000 benthic and pelagic species inhabiting the Mediterranean Sea, combined with climatic stability and heterogeneity metrics of the seascape. We identified important areas based on both biological and climatic criteria, where conservation focus should be given in priority when designing a three-dimensional, climate-smart protected area network. We detected spatially concise, conservation priority areas, distributed around the basin, that protected marine areas almost equally across all depth zones. Our approach highlights the importance of deep sea zones as priority areas to meet conservation targets for future marine biodiversity, while suggesting that spatial prioritization schemes, that focus on a static two-dimensional distribution of biodiversity data, might fail to englobe both the vertical properties of species distributions and the fine and larger-scale impacts associated with climate change., (© 2022 John Wiley & Sons Ltd.)

Published
2022
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35. Global assessment of marine and freshwater recreational fish reveals mismatch in climate change vulnerability and conservation effort.

Author

Nyboer EA, Lin HY, Bennett JR, Gabriel J, Twardek W, Chhor AD, Daly L, Dolson S, Guitard E, Holder P, Mozzon CM, Trahan A, Zimmermann D, Kesner-Reyes K, Garilao C, Kaschner K, and Cooke SJ

Subjects
Animals, Conservation of Natural Resources, Ecosystem, Fisheries, Fresh Water, Climate Change, Fishes
Abstract

Recreational fisheries contribute substantially to the sociocultural and economic well-being of coastal and riparian regions worldwide, but climate change threatens their sustainability. Fishery managers require information on how climate change will impact key recreational species; however, the absence of a global assessment hinders both directed and widespread conservation efforts. In this study, we present the first global climate change vulnerability assessment of recreationally targeted fish species from marine and freshwater environments (including diadromous fishes). We use climate change projections and data on species' physiological and ecological traits to quantify and map global climate vulnerability and analyze these patterns alongside the indices of socioeconomic value and conservation effort to determine where efforts are sufficient and where they might fall short. We found that over 20% of recreationally targeted fishes are vulnerable to climate change under a high emission scenario. Overall, marine fishes had the highest number of vulnerable species, concentrated in regions with sensitive habitat types (e.g., coral reefs). However, freshwater fishes had higher proportions of species at risk from climate change, with concentrations in northern Europe, Australia, and southern Africa. Mismatches in conservation effort and vulnerability were found within all regions and life-history groups. A key pattern was that current conservation effort focused primarily on marine fishes of high socioeconomic value rather than on the freshwater and diadromous fishes that were predicted to be proportionately more vulnerable. While several marine regions were notably lacking in protection (e.g., Caribbean Sea, Banda Sea), only 19% of vulnerable marine species were without conservation effort. By contrast, 72% of freshwater fishes and 33% of diadromous fishes had no measures in place, despite their high vulnerability and cultural value. The spatial and taxonomic analyses presented here provide guidance for the future conservation and management of recreational fisheries as climate change progresses., (© 2021 John Wiley & Sons Ltd.)

Published
2021
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36. Circumpolar phylogeography and demographic history of beluga whales reflect past climatic fluctuations.

Author

Skovrind M, Louis M, Westbury MV, Garilao C, Kaschner K, Castruita JAS, Gopalakrishnan S, Knudsen SW, Haile JS, Dalén L, Meshchersky IG, Shpak OV, Glazov DM, Rozhnov VV, Litovka DI, Krasnova VV, Chernetsky AD, Bel'kovich VM, Lydersen C, Kovacs KM, Heide-Jørgensen MP, Postma L, Ferguson SH, and Lorenzen ED

Subjects
Animals, Arctic Regions, Demography, Ecosystem, Oceans and Seas, Pacific Ocean, Phylogeography, Beluga Whale genetics
Abstract

Several Arctic marine mammal species are predicted to be negatively impacted by rapid sea ice loss associated with ongoing ocean warming. However, consequences for Arctic whales remain uncertain. To investigate how Arctic whales responded to past climatic fluctuations, we analysed 206 mitochondrial genomes from beluga whales (Delphinapterus leucas) sampled across their circumpolar range, and four nuclear genomes, covering both the Atlantic and the Pacific Arctic region. We found four well-differentiated mitochondrial lineages, which were established before the onset of the last glacial expansion ~110 thousand years ago. Our findings suggested these lineages diverged in allopatry, reflecting isolation of populations during glacial periods when the Arctic sea-shelf was covered by multiyear sea ice. Subsequent population expansion and secondary contact between the Atlantic and Pacific Oceans shaped the current geographic distribution of lineages, and may have facilitated mitochondrial introgression. Our demographic reconstructions based on both mitochondrial and nuclear genomes showed markedly lower population sizes during the Last Glacial Maximum (LGM) compared to the preceding Eemian and current Holocene interglacial periods. Habitat modelling similarly revealed less suitable habitat during the LGM (glacial) than at present (interglacial). Together, our findings suggested the association between climate, population size, and available habitat in belugas. Forecasts for year 2100 showed that beluga habitat will decrease and shift northwards as oceans continue to warm, putatively leading to population declines in some beluga populations. Finally, we identified vulnerable populations which, if extirpated as a consequence of ocean warming, will lead to a substantial decline of species-wide haplotype diversity., (© 2021 John Wiley & Sons Ltd.)

Published
2021
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37. No leading-edge effect in North Atlantic harbor porpoises: Evolutionary and conservation implications.

Author

Ben Chehida Y, Loughnane R, Thumloup J, Kaschner K, Garilao C, Rosel PE, and Fontaine MC

Abstract

Understanding species responses to past environmental changes can help forecast how they will cope with ongoing climate changes. Harbor porpoises are widely distributed in the North Atlantic and were deeply impacted by the Pleistocene changes with the split of three subspecies. Despite major impacts of fisheries on natural populations, little is known about population connectivity and dispersal, how they reacted to the Pleistocene changes, and how they will evolve in the future. Here, we used phylogenetics, population genetics, and predictive habitat modeling to investigate population structure and phylogeographic history of the North Atlantic porpoises. A total of 925 porpoises were characterized at 10 microsatellite loci and one quarter of the mitogenome (mtDNA). A highly divergent mtDNA lineage was uncovered in one porpoise off Western Greenland, suggesting that a cryptic group may occur and could belong to a recently discovered mesopelagic ecotype off Greenland. Aside from it and the southern subspecies, spatial genetic variation showed that porpoises from both sides of the North Atlantic form a continuous system belonging to the same subspecies ( Phocoena phocoena phocoena ). Yet, we identified important departures from random mating and restricted dispersal forming a highly significant isolation by distance (IBD) at both mtDNA and nuclear markers. A ten times stronger IBD at mtDNA compared with nuclear loci supported previous evidence of female philopatry. Together with the lack of spatial trends in genetic diversity, this IBD suggests that migration-drift equilibrium has been reached, erasing any genetic signal of a leading-edge effect that accompanied the predicted recolonization of the northern habitats freed from Pleistocene ice. These results illuminate the processes shaping porpoise population structure and provide a framework for designing conservation strategies and forecasting future population evolution., Competing Interests: The authors declare that they have no conflict of interest., (© 2021 The Authors. Evolutionary Applications published by John Wiley & Sons Ltd.)

Published
2021
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38. Protecting the global ocean for biodiversity, food and climate.

Author

Sala E, Mayorga J, Bradley D, Cabral RB, Atwood TB, Auber A, Cheung W, Costello C, Ferretti F, Friedlander AM, Gaines SD, Garilao C, Goodell W, Halpern BS, Hinson A, Kaschner K, Kesner-Reyes K, Leprieur F, McGowan J, Morgan LE, Mouillot D, Palacios-Abrantes J, Possingham HP, Rechberger KD, Worm B, and Lubchenco J

Subjects
Animals, Carbon Sequestration, Fisheries, Geologic Sediments chemistry, Human Activities, International Cooperation, Biodiversity, Climate, Conservation of Natural Resources, Food Supply, Global Warming prevention & control
Abstract

The ocean contains unique biodiversity, provides valuable food resources and is a major sink for anthropogenic carbon. Marine protected areas (MPAs) are an effective tool for restoring ocean biodiversity and ecosystem services 1,2 , but at present only 2.7% of the ocean is highly protected 3 . This low level of ocean protection is due largely to conflicts with fisheries and other extractive uses. To address this issue, here we developed a conservation planning framework to prioritize highly protected MPAs in places that would result in multiple benefits today and in the future. We find that a substantial increase in ocean protection could have triple benefits, by protecting biodiversity, boosting the yield of fisheries and securing marine carbon stocks that are at risk from human activities. Our results show that most coastal nations contain priority areas that can contribute substantially to achieving these three objectives of biodiversity protection, food provision and carbon storage. A globally coordinated effort could be nearly twice as efficient as uncoordinated, national-level conservation planning. Our flexible prioritization framework could help to inform both national marine spatial plans 4 and global targets for marine conservation, food security and climate action.

Published
2021
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40. Influence of past climate change on phylogeography and demographic history of narwhals, Monodon monoceros .

Author

Louis M, Skovrind M, Samaniego Castruita JA, Garilao C, Kaschner K, Gopalakrishnan S, Haile JS, Lydersen C, Kovacs KM, Garde E, Heide-Jørgensen MP, Postma L, Ferguson SH, Willerslev E, and Lorenzen ED

Subjects
Animals, Arctic Regions, Demography, Ecosystem, Genome, Mitochondrial, Climate Change, Phylogeography, Whales psychology
Abstract

The Arctic is warming at an unprecedented rate, with unknown consequences for endemic fauna. However, Earth has experienced severe climatic oscillations in the past, and understanding how species responded to them might provide insight into their resilience to near-future climatic predictions. Little is known about the responses of Arctic marine mammals to past climatic shifts, but narwhals ( Monodon monoceros ) are considered one of the endemic Arctic species most vulnerable to environmental change. Here, we analyse 121 complete mitochondrial genomes from narwhals sampled across their range and use them in combination with species distribution models to elucidate the influence of past and ongoing climatic shifts on their population structure and demographic history. We find low levels of genetic diversity and limited geographic structuring of genetic clades. We show that narwhals experienced a long-term low effective population size, which increased after the Last Glacial Maximum, when the amount of suitable habitat expanded. Similar post-glacial habitat release has been a key driver of population size expansion of other polar marine predators. Our analyses indicate that habitat availability has been critical to the success of narwhals, raising concerns for their fate in an increasingly warming Arctic.

Published
2020
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41. Postglacial Colonization of Northern Coastal Habitat by Bottlenose Dolphins: A Marine Leading-Edge Expansion?

Author

Nykänen M, Kaschner K, Dabin W, Brownlow A, Davison NJ, Deaville R, Garilao C, Kesner-Reyes K, Gilbert MTP, Penrose R, Islas-Villanueva V, Wales N, Ingram SN, Rogan E, Louis M, and Foote AD

Subjects
Animals, Biodiversity, DNA, Mitochondrial, Genetic Variation, Genetics, Population, Models, Theoretical, Phylogeny, Phylogeography, Population Density, Sequence Analysis, DNA, Bottle-Nosed Dolphin classification, Bottle-Nosed Dolphin genetics, Ecosystem
Abstract

Oscillations in the Earth's temperature and the subsequent retreating and advancing of ice-sheets around the polar regions are thought to have played an important role in shaping the distribution and genetic structuring of contemporary high-latitude populations. After the Last Glacial Maximum (LGM), retreating of the ice-sheets would have enabled early colonizers to rapidly occupy suitable niches to the exclusion of other conspecifics, thereby reducing genetic diversity at the leading-edge. Bottlenose dolphins (genus Tursiops) form distinct coastal and pelagic ecotypes, with finer-scale genetic structuring observed within each ecotype. We reconstruct the postglacial colonization of the Northeast Atlantic (NEA) by bottlenose dolphins using habitat modeling and phylogenetics. The AquaMaps model hindcasted suitable habitat for the LGM in the Atlantic lower latitude waters and parts of the Mediterranean Sea. The time-calibrated phylogeny, constructed with 86 complete mitochondrial genomes including 30 generated for this study and created using a multispecies coalescent model, suggests that the expansion to the available coastal habitat in the NEA happened via founder events starting ~15 000 years ago (95% highest posterior density interval: 4 900-26 400). The founders of the 2 distinct coastal NEA populations comprised as few as 2 maternal lineages that originated from the pelagic population. The low effective population size and genetic diversity estimated for the shared ancestral coastal population subsequent to divergence from the pelagic source population are consistent with leading-edge expansion. These findings highlight the legacy of the Late Pleistocene glacial cycles on the genetic structuring and diversity of contemporary populations., (© The American Genetic Association 2019. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published
2019
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42. Global assessment of marine biodiversity potentially threatened by offshore hydrocarbon activities.

Author

Venegas-Li R, Levin N, Morales-Barquero L, Kaschner K, Garilao C, and Kark S

Subjects
Animals, Ecosystem, Estuaries, Fossil Fuels adverse effects, Hydrocarbons, Aquatic Organisms, Biodiversity, Conservation of Natural Resources, Oil and Gas Fields
Abstract

Increasing global energy demands have led to the ongoing intensification of hydrocarbon extraction from marine areas. Hydrocarbon extractive activities pose threats to native marine biodiversity, such as noise, light, and chemical pollution, physical changes to the sea floor, invasive species, and greenhouse gas emissions. Here, we assessed at a global scale the spatial overlap between offshore hydrocarbon activities and marine biodiversity (>25,000 species, nine major ecosystems, and marine protected areas), and quantify the changes over time. We discovered that two-thirds of global offshore hydrocarbon activities occur in areas within the top 10% for species richness, range rarity, and proportional range rarity values globally. Thus, while hydrocarbon activities are undertaken in less than one percent of the ocean's area, they overlap with approximately 85% of all assessed species. Of conservation concern, 4% of species with the largest proportion of their range overlapping hydrocarbon activities are range restricted, potentially increasing their vulnerability to localized threats such as oil spills. While hydrocarbon activities have extended to greater depths since the mid-1990s, we found that the largest overlap is with coastal ecosystems, particularly estuaries, saltmarshes and mangroves. Furthermore, in most countries where offshore hydrocarbon exploration licensing blocks have been delineated, they do not overlap with marine protected areas (MPAs). Although this is positive in principle, many countries have far more licensing block areas than protected areas, and in some instances, MPA coverage is minimal. These findings suggest the need for marine spatial prioritization to help limit future spatial overlap between marine conservation priorities and hydrocarbon activities. Such prioritization can be informed by the spatial and quantitative baseline information provided here. In increasingly shared seascapes, prioritizing management actions that set both conservation and development targets could help minimize further declines of biodiversity and environmental changes at a global scale., (© 2019 John Wiley & Sons Ltd.)

Published
2019
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43. Metabolic asymmetry and the global diversity of marine predators.

Author

Grady JM, Maitner BS, Winter AS, Kaschner K, Tittensor DP, Record S, Smith FA, Wilson AM, Dell AI, Zarnetske PL, Wearing HJ, Alfaro B, and Brown JH

Subjects
Animals, Birds physiology, Fishes physiology, Mammals physiology, Models, Biological, Oceans and Seas, Phylogeny, Reptiles physiology, Temperature, Biodiversity, Body Temperature Regulation, Food Chain, Metabolism, Predatory Behavior
Abstract

Species richness of marine mammals and birds is highest in cold, temperate seas-a conspicuous exception to the general latitudinal gradient of decreasing diversity from the tropics to the poles. We compiled a comprehensive dataset for 998 species of sharks, fish, reptiles, mammals, and birds to identify and quantify inverse latitudinal gradients in diversity, and derived a theory to explain these patterns. We found that richness, phylogenetic diversity, and abundance of marine predators diverge systematically with thermoregulatory strategy and water temperature, reflecting metabolic differences between endotherms and ectotherms that drive trophic and competitive interactions. Spatial patterns of foraging support theoretical predictions, with total prey consumption by mammals increasing by a factor of 80 from the equator to the poles after controlling for productivity., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published
2019
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44. An inverse latitudinal gradient in speciation rate for marine fishes.

Author

Rabosky DL, Chang J, Title PO, Cowman PF, Sallan L, Friedman M, Kaschner K, Garilao C, Near TJ, Coll M, and Alfaro ME

Subjects
Animals, Aquatic Organisms, Biodiversity, Models, Biological, Phylogeny, Time Factors, Fishes classification, Genetic Speciation, Geographic Mapping, Temperature
Abstract

Far more species of organisms are found in the tropics than in temperate and polar regions, but the evolutionary and ecological causes of this pattern remain controversial 1,2 . Tropical marine fish communities are much more diverse than cold-water fish communities found at higher latitudes 3,4 , and several explanations for this latitudinal diversity gradient propose that warm reef environments serve as evolutionary 'hotspots' for species formation 5-8 . Here we test the relationship between latitude, species richness and speciation rate across marine fishes. We assembled a time-calibrated phylogeny of all ray-finned fishes (31,526 tips, of which 11,638 had genetic data) and used this framework to describe the spatial dynamics of speciation in the marine realm. We show that the fastest rates of speciation occur in species-poor regions outside the tropics, and that high-latitude fish lineages form new species at much faster rates than their tropical counterparts. High rates of speciation occur in geographical regions that are characterized by low surface temperatures and high endemism. Our results reject a broad class of mechanisms under which the tropics serve as an evolutionary cradle for marine fish diversity and raise new questions about why the coldest oceans on Earth are present-day hotspots of species formation.

Published
2018
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45. Demography or selection on linked cultural traits or genes? Investigating the driver of low mtDNA diversity in the sperm whale using complementary mitochondrial and nuclear genome analyses.

Author

Morin PA, Foote AD, Baker CS, Hancock-Hanser BL, Kaschner K, Mate BR, Mesnick SL, Pease VL, Rosel PE, and Alexander A

Subjects
Animals, Demography, Genetics, Population methods, Haplotypes genetics, Phylogeny, Phylogeography methods, Population Density, Cell Nucleus genetics, DNA, Mitochondrial genetics, Genetic Variation genetics, Mitochondria genetics, Sperm Whale genetics
Abstract

Mitochondrial DNA has been heavily utilized in phylogeography studies for several decades. However, underlying patterns of demography and phylogeography may be misrepresented due to coalescence stochasticity, selection, variation in mutation rates and cultural hitchhiking (linkage of genetic variation to culturally-transmitted traits affecting fitness). Cultural hitchhiking has been suggested as an explanation for low genetic diversity in species with strong social structures, counteracting even high mobility, abundance and limited barriers to dispersal. One such species is the sperm whale, which shows very limited phylogeographic structure and low mtDNA diversity despite a worldwide distribution and large population. Here, we use analyses of 175 globally distributed mitogenomes and three nuclear genomes to evaluate hypotheses of a population bottleneck/expansion vs. a selective sweep due to cultural hitchhiking or selection on mtDNA as the mechanism contributing to low worldwide mitochondrial diversity in sperm whales. In contrast to mtDNA control region (CR) data, mitogenome haplotypes are largely ocean-specific, with only one of 80 shared between the Atlantic and Pacific. Demographic analyses of nuclear genomes suggest low mtDNA diversity is consistent with a global reduction in population size that ended approximately 125,000 years ago, correlated with the Eemian interglacial. Phylogeographic analysis suggests that extant sperm whales descend from maternal lineages endemic to the Pacific during the period of reduced abundance and have subsequently colonized the Atlantic several times. Results highlight the apparent impact of past climate change, and suggest selection and hitchhiking are not the sole processes responsible for low mtDNA diversity in this highly social species., (© 2018 John Wiley & Sons Ltd.)

Published
2018
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46. Assessing cetacean surveys throughout the Mediterranean Sea: a gap analysis in environmental space.

Author

Mannocci L, Roberts JJ, Halpin PN, Authier M, Boisseau O, Bradai MN, Cañadas A, Chicote C, David L, Di-Méglio N, Fortuna CM, Frantzis A, Gazo M, Genov T, Hammond PS, Holcer D, Kaschner K, Kerem D, Lauriano G, Lewis T, Notarbartolo di Sciara G, Panigada S, Raga JA, Scheinin A, Ridoux V, Vella A, and Vella J

Abstract

Heterogeneous data collection in the marine environment has led to large gaps in our knowledge of marine species distributions. To fill these gaps, models calibrated on existing data may be used to predict species distributions in unsampled areas, given that available data are sufficiently representative. Our objective was to evaluate the feasibility of mapping cetacean densities across the entire Mediterranean Sea using models calibrated on available survey data and various environmental covariates. We aggregated 302,481 km of line transect survey effort conducted in the Mediterranean Sea within the past 20 years by many organisations. Survey coverage was highly heterogeneous geographically and seasonally: large data gaps were present in the eastern and southern Mediterranean and in non-summer months. We mapped the extent of interpolation versus extrapolation and the proportion of data nearby in environmental space when models calibrated on existing survey data were used for prediction across the entire Mediterranean Sea. Using model predictions to map cetacean densities in the eastern and southern Mediterranean, characterised by warmer, less productive waters, and more intense eddy activity, would lead to potentially unreliable extrapolations. We stress the need for systematic surveys of cetaceans in these environmentally unique Mediterranean waters, particularly in non-summer months.

Published
2018
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47. Aligning marine species range data to better serve science and conservation.

Author

O'Hara CC, Afflerbach JC, Scarborough C, Kaschner K, and Halpern BS

Subjects
Animals, Models, Theoretical, Ursidae, Biodiversity, Conservation of Natural Resources methods, Marine Biology
Abstract

Species distribution data provide the foundation for a wide range of ecological research studies and conservation management decisions. Two major efforts to provide marine species distributions at a global scale are the International Union for Conservation of Nature (IUCN), which provides expert-generated range maps that outline the complete extent of a species' distribution; and AquaMaps, which provides model-generated species distribution maps that predict areas occupied by the species. Together these databases represent 24,586 species (93.1% within AquaMaps, 16.4% within IUCN), with only 2,330 shared species. Differences in intent and methodology can result in very different predictions of species distributions, which bear important implications for scientists and decision makers who rely upon these datasets when conducting research or informing conservation policy and management actions. Comparing distributions for the small subset of species with maps in both datasets, we found that AquaMaps and IUCN range maps show strong agreement for many well-studied species, but our analysis highlights several key examples in which introduced errors drive differences in predicted species ranges. In particular, we find that IUCN maps greatly overpredict coral presence into unsuitably deep waters, and we show that some AquaMaps computer-generated default maps (only 5.7% of which have been reviewed by experts) can produce odd discontinuities at the extremes of a species' predicted range. We illustrate the scientific and management implications of these tradeoffs by repeating a global analysis of gaps in coverage of marine protected areas, and find significantly different results depending on how the two datasets are used. By highlighting tradeoffs between the two datasets, we hope to encourage increased collaboration between taxa experts and large scale species distribution modeling efforts to further improve these foundational datasets, helping to better inform science and policy recommendations around understanding, managing, and protecting marine biodiversity.

Published
2017
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48. Geographic and temporal dynamics of a global radiation and diversification in the killer whale.

Author

Morin PA, Parsons KM, Archer FI, Ávila-Arcos MC, Barrett-Lennard LG, Dalla Rosa L, Duchêne S, Durban JW, Ellis GM, Ferguson SH, Ford JK, Ford MJ, Garilao C, Gilbert MT, Kaschner K, Matkin CO, Petersen SD, Robertson KM, Visser IN, Wade PR, Ho SY, and Foote AD

Subjects
Animals, Bayes Theorem, Cell Nucleus genetics, DNA, Mitochondrial genetics, Ecosystem, Ecotype, Models, Theoretical, Molecular Sequence Data, Phylogeny, Phylogeography, Polymorphism, Single Nucleotide, Population Dynamics, Sequence Analysis, DNA, Biological Evolution, Climate Change, Genetic Variation, Whale, Killer genetics
Abstract

Global climate change during the Late Pleistocene periodically encroached and then released habitat during the glacial cycles, causing range expansions and contractions in some species. These dynamics have played a major role in geographic radiations, diversification and speciation. We investigate these dynamics in the most widely distributed of marine mammals, the killer whale (Orcinus orca), using a global data set of over 450 samples. This marine top predator inhabits coastal and pelagic ecosystems ranging from the ice edge to the tropics, often exhibiting ecological, behavioural and morphological variation suggestive of local adaptation accompanied by reproductive isolation. Results suggest a rapid global radiation occurred over the last 350 000 years. Based on habitat models, we estimated there was only a 15% global contraction of core suitable habitat during the last glacial maximum, and the resources appeared to sustain a constant global effective female population size throughout the Late Pleistocene. Reconstruction of the ancestral phylogeography highlighted the high mobility of this species, identifying 22 strongly supported long-range dispersal events including interoceanic and interhemispheric movement. Despite this propensity for geographic dispersal, the increased sampling of this study uncovered very few potential examples of ancestral dispersal among ecotypes. Concordance of nuclear and mitochondrial data further confirms genetic cohesiveness, with little or no current gene flow among sympatric ecotypes. Taken as a whole, our data suggest that the glacial cycles influenced local populations in different ways, with no clear global pattern, but with secondary contact among lineages following long-range dispersal as a potential mechanism driving ecological diversification., (© 2015 John Wiley & Sons Ltd.)

Published
2015
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49. Climate impacts on transocean dispersal and habitat in gray whales from the Pleistocene to 2100.

Author

Alter SE, Meyer M, Post K, Czechowski P, Gravlund P, Gaines C, Rosenbaum HC, Kaschner K, Turvey ST, van der Plicht J, Shapiro B, and Hofreiter M

Subjects
Animals, Arctic Regions, Atlantic Ocean, DNA, Mitochondrial genetics, Ecosystem, Fossils, Haplotypes, Models, Biological, Molecular Sequence Data, Phylogeography, Population Dynamics, Sequence Analysis, DNA, Climate Change, Genetic Variation, Whales genetics
Abstract

Arctic animals face dramatic habitat alteration due to ongoing climate change. Understanding how such species have responded to past glacial cycles can help us forecast their response to today's changing climate. Gray whales are among those marine species likely to be strongly affected by Arctic climate change, but a thorough analysis of past climate impacts on this species has been complicated by lack of information about an extinct population in the Atlantic. While little is known about the history of Atlantic gray whales or their relationship to the extant Pacific population, the extirpation of the Atlantic population during historical times has been attributed to whaling. We used a combination of ancient and modern DNA, radiocarbon dating and predictive habitat modelling to better understand the distribution of gray whales during the Pleistocene and Holocene. Our results reveal that dispersal between the Pacific and Atlantic was climate dependent and occurred both during the Pleistocene prior to the last glacial period and the early Holocene immediately following the opening of the Bering Strait. Genetic diversity in the Atlantic declined over an extended interval that predates the period of intensive commercial whaling, indicating this decline may have been precipitated by Holocene climate or other ecological causes. These first genetic data for Atlantic gray whales, particularly when combined with predictive habitat models for the year 2100, suggest that two recent sightings of gray whales in the Atlantic may represent the beginning of the expansion of this species' habitat beyond its currently realized range., (© 2015 John Wiley & Sons Ltd.)

Published
2015
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50. Global priorities for marine biodiversity conservation.

Author

Selig ER, Turner WR, Troëng S, Wallace BP, Halpern BS, Kaschner K, Lascelles BG, Carpenter KE, and Mittermeier RA

Subjects
Animals, Climate, Fishes physiology, Geography, Human Activities, Humans, Species Specificity, Water Pollution, Biodiversity, Conservation of Natural Resources economics, Internationality, Oceans and Seas
Abstract

In recent decades, many marine populations have experienced major declines in abundance, but we still know little about where management interventions may help protect the highest levels of marine biodiversity. We used modeled spatial distribution data for nearly 12,500 species to quantify global patterns of species richness and two measures of endemism. By combining these data with spatial information on cumulative human impacts, we identified priority areas where marine biodiversity is most and least impacted by human activities, both within Exclusive Economic Zones (EEZs) and Areas Beyond National Jurisdiction (ABNJ). Our analyses highlighted places that are both accepted priorities for marine conservation like the Coral Triangle, as well as less well-known locations in the southwest Indian Ocean, western Pacific Ocean, Arctic and Antarctic Oceans, and within semi-enclosed seas like the Mediterranean and Baltic Seas. Within highly impacted priority areas, climate and fishing were the biggest stressors. Although new priorities may arise as we continue to improve marine species range datasets, results from this work are an essential first step in guiding limited resources to regions where investment could best sustain marine biodiversity.

Published
2014
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