Your search keyword '"Abrahms, B."' showing total 42 results

1. SensorDrop: A system to remotely detach individual sensors from wildlife tracking collars

Author

Rafiq, K., primary, Appleby, R. G., additional, Davies, A., additional, and Abrahms, B., additional

Published

2023

2. Effects of body size on estimation of mammalian area requirements

Author

Noonan, M.J., Fleming, C.H., Tucker, M.A., Kays, R., Harrison, A.L., Crofoot, M.C., Abrahms, B., Alberts, S.C., Ali, A.H., Altmann, J., Antunes, P.C., Attias, N., Belant, J.L., Beyer, D.E., Jr., Bidner, L.R., Blaum, N., Boone, R.B., Caillaud, D., Paula, R.C. de, Torre, J.A. de la, Dekker, J., DePerno, C.S., Farhadinia, M., Fennessy, J., Fichtel, C., Fischer, C., Ford, A., Goheen, J.R., Havmoller, R.W., Hirsch, B.T., Hurtado, C., Isbell, L.A., Janssen, Rene, Jeltsch, F., Kaczensky, P., Kaneko, Y., Kappeler, P., Katna, A., Kauffman, M., Koch, F., Kulkarni, A., LaPoint, S., Leimgruber, P., Macdonald, D.W., Markham, A.C., McMahon, L., Mertes, K., Moorman, C.E., Morato, R.G., Mossbrucker, A.M., Mourao, G., O'Connor, D., Oliveira-Santos, L.G.R., Pastorini, J., Patterson, B.D., Rachlow, J., Ranglack, D.H., Reid, N., Scantlebury, D.M., Scott, D.M., Selva, N., Sergiel, A., Songer, M., Songsasen, N., Stabach, J.A., Stacy-Dawes, J., Swingen, M.B., Thompson, J.J., Ullmann, W., Vanak, A.T., Thaker, M., Wilson, J.W., Yamazaki, K., Yarnell, R.W., Zieba, F., Zwijacz-Kozica, T., Fagan, W.F., Mueller, T., Calabrese, J.M., Noonan, M.J., Fleming, C.H., Tucker, M.A., Kays, R., Harrison, A.L., Crofoot, M.C., Abrahms, B., Alberts, S.C., Ali, A.H., Altmann, J., Antunes, P.C., Attias, N., Belant, J.L., Beyer, D.E., Jr., Bidner, L.R., Blaum, N., Boone, R.B., Caillaud, D., Paula, R.C. de, Torre, J.A. de la, Dekker, J., DePerno, C.S., Farhadinia, M., Fennessy, J., Fichtel, C., Fischer, C., Ford, A., Goheen, J.R., Havmoller, R.W., Hirsch, B.T., Hurtado, C., Isbell, L.A., Janssen, Rene, Jeltsch, F., Kaczensky, P., Kaneko, Y., Kappeler, P., Katna, A., Kauffman, M., Koch, F., Kulkarni, A., LaPoint, S., Leimgruber, P., Macdonald, D.W., Markham, A.C., McMahon, L., Mertes, K., Moorman, C.E., Morato, R.G., Mossbrucker, A.M., Mourao, G., O'Connor, D., Oliveira-Santos, L.G.R., Pastorini, J., Patterson, B.D., Rachlow, J., Ranglack, D.H., Reid, N., Scantlebury, D.M., Scott, D.M., Selva, N., Sergiel, A., Songer, M., Songsasen, N., Stabach, J.A., Stacy-Dawes, J., Swingen, M.B., Thompson, J.J., Ullmann, W., Vanak, A.T., Thaker, M., Wilson, J.W., Yamazaki, K., Yarnell, R.W., Zieba, F., Zwijacz-Kozica, T., Fagan, W.F., Mueller, T., and Calabrese, J.M.

Abstract

Contains fulltext : 226766.pdf (publisher's version ) (Open Access)

Published

2020

3. Does wildlife resource selection accurately inform corridor conservation?

Author

Abrahms, B, Sawyer, S C, Jordan, N R, McNutt, J W, Wilson, A M, and Brashares, J S

Published

2017

4. Lessons from integrating behaviour and resource selection: activity-specific responses of African wild dogs to roads

Author

Abrahms, B, Jordan, N R, Golabek, K A, McNutt, J W, Wilson, A M, and Brashares, J S

Abstract

Understanding how anthropogenic features affect species' abilities to move within landscapes is essential to conservation planning and requires accurate assessment of resource selection for movement by focal species. Yet, the extent to which an individual's behavioural state (e.g. foraging, resting, commuting) influences resource selection has largely been ignored. Recent advances in Global Positioning System (GPS) tracking technology can fill this gap by associating distinct behavioural states with location data. We investigated the role of behaviour in determining the responses of an endangered species of carnivore, the African wild dog Lycaon pictus, to one of the most widespread forms of landscape alteration globally: road systems. We collected high‐resolution GPS and activity data from 13 wild dogs in northern Botswana over a 2‐year period. We employed a step selection framework to measure resource selection across three behavioural states identified from activity data (high‐speed running, resting and travelling) and across a gradient of habitats and seasons, and compared these outputs to a full model that did not parse for behaviour. The response of wild dogs to roads varied markedly with both the behavioural and the landscape contexts in which roads were encountered. Specifically, wild dogs selected roads when travelling, ignored roads when high‐speed running and avoided roads when resting. This distinction was not evident when all movement data were considered together in the full model. When travelling, selection for roads increased in denser vegetative environments, suggesting that roads may enhance movement for this species. Our findings indicate that including behavioural information in resource selection models is critical to understanding wildlife responses to landscape features and suggest that successful application of resource selection analyses to conservation planning requires explicit examination of the behavioural contexts in which movement occurs. Thus, behaviour‐specific step selection functions offer a powerful tool for identifying resource selection patterns for animal behaviours of conservation significance.

Published

2015

5. Response

Author

Withey, L, Seto, K, McCauley, DJ, Fiorella, KJ, Marsh, RA, Abrahms, B, Nuñez, TA, Golden, CD, and Brashares, JS

Published

2014

6. Lessons from integrating behaviour and resource selection: activity‐specific responses of African wild dogs to roads

Author

Abrahms, B., primary, Jordan, N. R., additional, Golabek, K. A., additional, McNutt, J. W., additional, Wilson, A. M., additional, and Brashares, J. S., additional

Published

2015

7. Fauna in decline--Response

Author

Withey, L., primary, Seto, K., additional, McCauley, D. J., additional, Fiorella, K. J., additional, Marsh, R. A., additional, Abrahms, B., additional, Nunez, T. A., additional, Golden, C. D., additional, and Brashares, J. S., additional

Published

2014

8. Lessons from integrating behaviour and resource selection: activity-specific responses of African wild dogs to roads.

Author

Abrahms, B., Jordan, N. R., Golabek, K. A., McNutt, J. W., Wilson, A. M., and Brashares, J. S.

Subjects

*WILDLIFE relocation, *WILD dogs, *WILDLIFE conservation, *ANIMAL behavior, *CONSERVATION of natural resources

Abstract

Understanding how anthropogenic features affect species' abilities to move within landscapes is essential to conservation planning and requires accurate assessment of resource selection for movement by focal species. Yet, the extent to which an individual's behavioural state (e.g. foraging, resting, commuting) influences resource selection has largely been ignored. Recent advances in Global Positioning System ( GPS) tracking technology can fill this gap by associating distinct behavioural states with location data. We investigated the role of behaviour in determining the responses of an endangered species of carnivore, the African wild dog L ycaon pictus, to one of the most widespread forms of landscape alteration globally: road systems. We collected high-resolution GPS and activity data from 13 wild dogs in northern Botswana over a 2-year period. We employed a step selection framework to measure resource selection across three behavioural states identified from activity data (high-speed running, resting and travelling) and across a gradient of habitats and seasons, and compared these outputs to a full model that did not parse for behaviour. The response of wild dogs to roads varied markedly with both the behavioural and the landscape contexts in which roads were encountered. Specifically, wild dogs selected roads when travelling, ignored roads when high-speed running and avoided roads when resting. This distinction was not evident when all movement data were considered together in the full model. When travelling, selection for roads increased in denser vegetative environments, suggesting that roads may enhance movement for this species. Our findings indicate that including behavioural information in resource selection models is critical to understanding wildlife responses to landscape features and suggest that successful application of resource selection analyses to conservation planning requires explicit examination of the behavioural contexts in which movement occurs. Thus, behaviour-specific step selection functions offer a powerful tool for identifying resource selection patterns for animal behaviours of conservation significance. [ABSTRACT FROM AUTHOR]

Published

2016

9. Removing institutional barriers to long-term fieldwork is critical for advancing ecology.

Author

Rafiq K, Jordan NR, McNutt JW, Neelo J, Attias N, Boersma D, Palmer MS, Ruesink J, and Abrahms B

Abstract

Long-term fieldwork is essential for ecology and conservation, but is hindered by institutional barriers, such as the publish-or-perish culture of academia, and funding limitations. Here, we discuss these challenges and propose strategies to overcome them, such as broadening evaluation metrics and supporting inclusivity, to advance scientific insight and societal equity., (Copyright © 2024. Published by Elsevier Ltd.)

Published

2024

10. Droughts reshape apex predator space use and intraguild overlap.

Author

West L, Rafiq K, Converse SJ, Wilson AM, Jordan NR, Golabek KA, McNutt JW, and Abrahms B

Subjects

Animals, Climate Change, Acinonyx physiology, Canidae physiology, Panthera physiology, Food Chain, Droughts, Predatory Behavior

Abstract

Droughts are increasing in frequency and severity globally due to climate change, leading to changes in resource availability that may have cascading effects on animal ecology. Resource availability is a key driver of animal space use, which in turn influences interspecific interactions like intraguild competition. Understanding how climate-induced changes in resource availability influence animal space use, and how species-specific responses scale up to affect intraguild dynamics, is necessary for predicting broader community-level responses to climatic changes. Although several studies have demonstrated the ecological impacts of drought, the behavioural responses of individuals that scale up to these broader-scale effects are not well known, particularly among animals in top trophic levels like large carnivores. Furthermore, we currently lack understanding of how the impacts of climate variability on individual carnivore behaviour are linked to intraguild dynamics, in part because multi-species datasets collected at timescales relevant to climatic changes are rare. Using 11 years of GPS data from four sympatric large carnivore species in southern Africa-lions (Panthera leo), leopards (Panthera pardus), African wild dogs (Lycaon pictus) and cheetahs (Acinonyx jubatus)-spanning 4 severe drought events, we test whether drought conditions impact (1) large carnivore space use, (2) broad-scale intraguild spatial overlap and (3) fine-scale intraguild interactions. Drought conditions expanded space use across species, with carnivores increasing their monthly home range sizes by 35% (wild dogs) to 66% (leopards). Drought conditions increased the amount of spatial overlap between lions and subordinate felids (cheetahs and leopards) by up to 119%, but only lion-cheetah encounter rates were affected by these changes, declining in response to drought. Our findings reveal that drought has a clear signature on the space use of multiple sympatric large carnivore species, which can alter spatiotemporal partitioning between competing species. Our study thereby illuminates the links between environmental change, animal behaviour and intraguild dynamics. While fine-scale avoidance strategies may facilitate intraguild coexistence during periodic droughts, large carnivore conservation may require considerable expansion of protected areas or revised human-carnivore coexistence strategies to accommodate the likely long-term increased space demands of large carnivores under projected increases in drought intensity., (© 2024 The Author(s). Journal of Animal Ecology © 2024 British Ecological Society. This article has been contributed to by U.S. Government employees and their work is in the public domain in the USA.)

Published

2024

11. Maximizing biological insights from instruments attached to animals.

Author

Beltran RS, Kilpatrick AM, Picardi S, Abrahms B, Barrile GM, Oestreich WK, Smith JA, Czapanskiy MF, Favilla AB, Reisinger RR, Kendall-Bar JM, Payne AR, Savoca MS, Palance DG, Andrzejaczek S, Shen DM, Adachi T, Costa DP, Storm NA, Hale CM, and Robinson PW

Abstract

Instruments attached to animals ('biologgers') have facilitated extensive discoveries about the patterns, causes, and consequences of animal behavior. Here, we present examples of how biologging can deepen our fundamental understanding of ecosystems and our applied understanding of global change impacts by enabling tests of ecological theory. Applying the iterative process of science to biologging has enabled a diverse set of insights, including social and experiential learning in long-distance migrants, state-dependent risk aversion in foraging predators, and resource abundance driving movement across taxa. Now, biologging is poised to tackle questions and refine ecological theories at increasing levels of complexity by integrating measurements from numerous individuals, merging datasets from multiple species and their environments, and spanning disciplines, including physiology, behavior and demography., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2024

12. Tracking individual animals can reveal the mechanisms of species loss.

Author

Yanco SW, Rutz C, Abrahms B, Cooper NW, Marra PP, Mueller T, Weeks BC, Wikelski M, and Oliver RY

Abstract

As biodiversity loss continues, targeted conservation interventions are increasingly necessary. Stemming species loss requires mechanistic understanding of the processes governing population dynamics. However, this information is unavailable for most animals because it requires data that are difficult to collect using traditional methods. Advances in animal tracking technology have generated an avalanche of high-resolution observations for a growing list of species around the globe. To date, most research using these data has focused on questions about animal behavior, with less emphasis on population processes. Here, we argue that tracking data are uniquely poised to bring powerful new insights to the urgent, global problem of halting species extinctions by revealing when, where, how, and why populations are changing., Competing Interests: Declaration of interests None declared by authors., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

13. Anthropogenic impacts at the interface of animal spatial and social behaviour.

Author

Gaynor KM, Abrahms B, Manlove KR, Oestreich WK, and Smith JA

Subjects

Animals, Anthropogenic Effects, Humans, Animals, Wild, Spatial Behavior, Social Behavior, Ecosystem, Behavior, Animal, Conservation of Natural Resources

Abstract

Human disturbance is contributing to widespread, global changes in the distributions and densities of wild animals. These anthropogenic impacts on wildlife arise from multiple bottom-up and top-down pathways, including habitat loss, resource provisioning, climate change, pollution, infrastructure development, hunting and our direct presence. Animal behaviour is an important mechanism linking these disturbances to population outcomes, although these behavioural pathways are often complex and can remain obscured when different aspects of behaviour are studied in isolation from one another. The spatial-social interface provides a lens for understanding how an animal's spatial and social environments interact to determine its spatial and social phenotype (i.e. measurable characteristics of an individual), and how these phenotypes interact and feed back to reshape environments. Here, we review studies of animal behaviour at the spatial-social interface to understand and predict how human disturbance affects animal movement, distribution and intraspecific interactions, with consequences for the conservation of populations and ecosystems. By understanding the spatial-social mechanisms linking human disturbance to conservation outcomes, we can better design management interventions to mitigate undesired consequences of disturbance.This article is part of the theme issue 'The spatial-social interface: a theoretical and empirical integration'.

Published

2024

14. Evidence for seasonal migration by a cryptic top predator of the deep sea.

Author

Oestreich WK, Benoit-Bird KJ, Abrahms B, Margolina T, Joseph JE, Zhang Y, Rueda CA, and Ryan JP

Abstract

Background: In ecosystems influenced by strong seasonal variation in insolation, the fitness of diverse taxa depends on seasonal movements to track resources along latitudinal or elevational gradients. Deep pelagic ecosystems, where sunlight is extremely limited, represent Earth's largest habitable space and yet ecosystem phenology and effective animal movement strategies in these systems are little understood. Sperm whales (Physeter macrocephalus) provide a valuable acoustic window into this world: the echolocation clicks they produce while foraging in the deep sea are the loudest known biological sounds on Earth and convey detailed information about their behavior., Methods: We analyze seven years of continuous passive acoustic observations from the Central California Current System, using automated methods to identify both presence and demographic information from sperm whale echolocation clicks. By integrating empirical results with individual-level movement simulations, we test hypotheses about the movement strategies underlying sperm whales' long-distance movements in the Northeast Pacific., Results: We detect foraging sperm whales of all demographic groups year-round in the Central California Current System, but also identify significant seasonality in frequency of presence. Among several previously hypothesized movement strategies for this population, empirical acoustic observations most closely match simulated results from a population undertaking a "seasonal resource-tracking migration", in which individuals move to track moderate seasonal-latitudinal variation in resource availability., Discussion: Our findings provide evidence for seasonal movements in this cryptic top predator of the deep sea. We posit that these seasonal movements are likely driven by tracking of deep-sea resources, based on several lines of evidence: (1) seasonal-latitudinal patterns in foraging sperm whale detection across the Northeast Pacific; (2) lack of demographic variation in seasonality of presence; and (3) the match between simulations of seasonal resource-tracking migration and empirical results. We show that sperm whales likely track oceanographic seasonality in a manner similar to many surface ocean predators, but with dampened seasonal-latitudinal movement patterns. These findings shed light on the drivers of sperm whales' long-distance movements and the shrouded phenology of the deep-sea ecosystems in which they forage., (© 2024. The Author(s).)

Published

2024

15. Spatial match-mismatch between predators and prey under climate change.

Author

Carroll G, Abrahms B, Brodie S, and Cimino MA

Subjects

Animals, Climate Change, Food Chain, Predatory Behavior

Abstract

Climate change is driving a rapid redistribution of life on Earth. Variability in the rates, magnitudes and directions of species' shifts can alter spatial overlap between predators and prey, with the potential to decouple trophic interactions. Although phenological mismatches between predator requirements and prey availability under climate change are well-established, 'spatial match-mismatch' dynamics remain poorly understood. We synthesize global evidence for climate-driven changes in spatial predator-prey overlap resulting from species redistribution across marine and terrestrial domains. We show that spatial mismatches can have vastly different outcomes for predator populations depending on their diet specialization and role within the wider ecosystem. We illustrate ecosystem-level consequences of climate-driven changes in spatial predator-prey overlap, from restructuring food webs to altering socio-ecological interactions. It remains unclear how predator-prey overlap at the landscape scale relates to prey encounter and consumption rates at local scales, or how the spatial reorganization of food webs affects ecosystem function. We identify key research directions necessary to resolve the scale of ecological impacts caused by species redistribution under climate change., (© 2024. Springer Nature Limited.)

Published

2024

16. Global expansion of human-wildlife overlap in the 21st century.

Author

Ma D, Abrahms B, Allgeier J, Newbold T, Weeks BC, and Carter NH

Subjects

Humans, Animals, Biodiversity, Ecosystem, Population Density, Population Dynamics, Conservation of Natural Resources, Animals, Wild, Climate Change

Abstract

Understanding the extent to which people and wildlife overlap in space and time is critical for the conservation of biodiversity and ecological services. Yet, how global change will reshape the future of human-wildlife overlap has not been assessed. We show that the potential spatial overlap of global human populations and 22,374 terrestrial vertebrate species will increase across ~56.6% and decrease across only ~11.8% of the Earth's terrestrial surface by 2070. Increases are driven primarily by intensification of human population densities, not change in wildlife distributions caused by climate change. The strong spatial heterogeneity of future human-wildlife overlap found in our study makes it clear that local context is imperative to consider, and more targeted area-based land-use planning should be integrated into systematic conservation planning.

Published

2024

17. Increasing environmental variability inhibits evolutionary rescue in a long-lived vertebrate.

Author

Clark-Wolf TJ, Boersma PD, Plard F, Rebstock GA, and Abrahms B

Subjects

Animals, Adaptation, Physiological, Extinction, Biological, Selection, Genetic, Environment, Ecosystem, Spheniscidae physiology, Biological Evolution, Climate Change

Abstract

Evolutionary rescue, whereby adaptive evolutionary change rescues populations from extinction, is theorized to enable imperiled animal populations to persist under increasing anthropogenic change. Despite a large body of evidence in theoretical and laboratory settings, the potential for evolutionary rescue to be a viable adaptation process for free-ranging animals remains unknown. Here, we leverage a 38-year dataset following the fates of 53,959 Magellanic penguins ( Spheniscus magellanicus ) to investigate whether a free-ranging vertebrate species can morphologically adapt to long-term environmental change sufficiently to promote population persistence. Despite strong selective pressures, we found that penguins did not adapt morphologically to long-term environmental changes, leading to projected population extirpation. Fluctuating selection benefited larger penguins in some environmental contexts, and smaller penguins in others, ultimately mitigating their ability to adapt under increasing environmental variability. Under future climate projections, we found that the species cannot be rescued by adaptation, suggesting similar constraints for other long-lived species. Such results reveal how fluctuating selection driven by environmental variability can inhibit adaptation under long-term environmental change. Our eco-evolutionary approach helps explain the lack of adaptation and evolutionary rescue in response to environmental change observed in many animal species., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

18. Long-distance communication can enable collective migration in a dynamic seascape.

Author

Dodson S, Oestreich WK, Savoca MS, Hazen EL, Bograd SJ, Ryan JP, Fiechter J, and Abrahms B

Subjects

Animals, Ecosystem, Whales physiology, Animal Communication, Seasons, Social Behavior, Animal Migration physiology

Abstract

Social information is predicted to enhance the quality of animals' migratory decisions in dynamic ecosystems, but the relative benefits of social information in the long-range movements of marine megafauna are unknown. In particular, whether and how migrants use nonlocal information gained through social communication at the large spatial scale of oceanic ecosystems remains unclear. Here we test hypotheses about the cues underlying timing of blue whales' breeding migration in the Northeast Pacific via individual-based models parameterized by empirical behavioral data. Comparing emergent patterns from individual-based models to individual and population-level empirical metrics of migration timing, we find that individual whales likely rely on both personal and social sources of information about forage availability in deciding when to depart from their vast and dynamic foraging habitat and initiate breeding migration. Empirical patterns of migratory phenology can only be reproduced by models in which individuals use long-distance social information about conspecifics' behavioral state, which is known to be encoded in the patterning of their widely propagating songs. Further, social communication improves pre-migration seasonal foraging performance by over 60% relative to asocial movement mechanisms. Our results suggest that long-range communication enhances the perceptual ranges of migrating whales beyond that of any individual, resulting in increased foraging performance and more collective migration timing. These findings indicate the value of nonlocal social information in an oceanic migrant and suggest the importance of long-distance acoustic communication in the collective migration of wide-ranging marine megafauna., (© 2024. The Author(s).)

Published

2024

19. Selection of planning unit size in dynamic management strategies to reduce human-wildlife conflict.

Author

Welch H, Liu OR, Riekkola L, Abrahms B, Hazen EL, and Samhouri JF

Subjects

Animals, Retrospective Studies, Balaenoptera physiology, Humpback Whale physiology, Brachyura physiology, Conservation of Natural Resources methods, Fisheries

Abstract

Conservation planning traditionally relies upon static reserves; however, there is increasing emphasis on dynamic management (DM) strategies that are flexible in space and time. Due to its novelty, DM lacks best practices to guide design and implementation. We assessed the effect of planning unit size in a DM tool designed to reduce entanglement of protected whales in vertical ropes of surface buoys attached to crab traps in the lucrative U.S. Dungeness crab (Metacarcinus magister) fishery. We conducted a retrospective analysis from 2009 to 2019 with modeled distributions of blue (Balaenoptera musculus) and humpback (Megaptera novaeangliae) whales and observed fisheries effort and revenue to evaluate the effect of 7 planning unit sizes on DM tool performance. We measured performance as avoided whale entanglement risk and protected fisheries revenue. Small planning units avoided up to $47 million of revenue loss and reduced entanglement risk by up to 25% compared to the large planning units currently in use by avoiding the incidental closure of areas with low biodiversity value and high fisheries revenue. However, large planning units were less affected by an unprecedented marine heat wave in 2014-2016 and by delays in information on the distributions of whales and the fishery. Our findings suggest that the choice of planning unit size will require decision-makers to navigate multiple socioecological considerations-rather than a one-size-fits-all approach-to separate wildlife from threats under a changing climate., (© 2024 The Authors. Conservation Biology published by Wiley Periodicals LLC on behalf of Society for Conservation Biology.)

Published

2024

20. The value of field research in academia.

Author

Rafiq K, Jordan NR, McNutt JW, Neelo J, Attias N, Boersma D, Palmer MS, Ruesink J, and Abrahms B

Published

2024

21. Increasing ambient temperatures trigger shifts in activity patterns and temporal partitioning in a large carnivore guild.

Author

Rafiq K, Jordan NR, Golabek K, McNutt JW, Wilson A, and Abrahms B

Subjects

Animals, Ecosystem, Temperature, Acinonyx, Carnivora physiology, Canidae, Panthera, Lions

Abstract

Shifts in species' interactions are implicated as an important proximate cause underpinning climate-change-related extinction. However, there is little empirical evidence on the pathways through which climate conditions, such as ambient temperature, impact community dynamics. The timing of activities is a widespread behavioural adaptation to environmental variability, and temporal partitioning is a key mechanism that facilitates coexistence, especially within large carnivore communities. We investigated temperature impacts on community dynamics through its influence on the diel activity of, and temporal partitioning amongst, four sympatric species of African large carnivores: lions ( Panthera leo ), leopards ( Panthera pardus ), cheetahs ( Acinonyx jubatus ) and African wild dogs ( Lycaon pictus ). Activity of all species was shaped by a combination of light availability and temperature, with most species becoming more nocturnal and decreasing activity levels with increasing temperatures. A nocturnal shift was most pronounced in cheetahs, the most diurnal species during median temperatures. This shift increased temporal overlap between cheetahs and other carnivore species by up to 15.92%, highlighting the importance of considering the responses of interacting sympatric species when inferring climate impacts on ecosystems. Our study provides evidence that temperature can significantly affect temporal partitioning within a carnivore guild by generating asymmetrical behavioural responses amongst functionally similar species.

Published

2023

22. Climate presses and pulses mediate the decline of a migratory predator.

Author

Clark-Wolf TJ, Dee Boersma P, Rebstock GA, and Abrahms B

Subjects

Animals, Population Dynamics, Life Cycle Stages, Climate Change, Seasons, Spheniscidae

Abstract

Long-term climate changes and extreme climate events differentially impact animal populations, yet whether and why these processes may act synergistically or antagonistically remains unknown. Disentangling these potentially interactive effects is critical for predicting population outcomes as the climate changes. Here, we leverage the "press-pulse" framework, which is used to describe ecological disturbances, to disentangle population responses in migratory Magellanic penguins to long-term changes in climate means and variability (presses) and extreme events (pulses) across multiple climate variables and life history stages. Using an unprecedented 38-y dataset monitoring 53,959 penguins, we show for the first time that the presses and pulses of climate change mediate the rate of population decline by differentially impacting different life stages. Moreover, we find that climate presses and pulses can work both synergistically and antagonistically to affect animal population persistence, necessitating the need to examine both processes in concert. Negative effects of terrestrial heat waves (pulses) on adult survival, for example, were countered by positive effects of long-term changes in oceanographic conditions in migratory grounds (presses) on juvenile and adult survival. Taken together, these effects led to predicted population extirpation under all future climate scenarios. This work underscores the importance of a holistic approach integrating multiple climate variables, life stages, and presses and pulses for predicting the persistence of animals under accelerating climate change.

Published

2023

23. Defining null expectations for animal site fidelity.

Author

Picardi S, Abrahms B, Gelzer E, Morrison TA, Verzuh T, and Merkle JA

Subjects

Animals, Motivation, Ecosystem

Abstract

Site fidelity-the tendency to return to previously visited locations-is widespread across taxa. Returns may be driven by several mechanisms, including memory, habitat selection, or chance; however, pattern-based definitions group different generating mechanisms under the same label of 'site fidelity', often assuming memory as the main driver. We propose an operational definition of site fidelity as patterns of return that deviate from a null expectation derived from a memory-free movement model. First, using agent-based simulations, we show that without memory, intrinsic movement characteristics and extrinsic landscape characteristics are key determinants of return patterns and that even random movements may generate substantial probabilities of return. Second, we illustrate how to implement our framework empirically to establish ecologically meaningful, system-specific null expectations for site fidelity. Our approach provides a conceptual and operational framework to test hypotheses on site fidelity across systems and scales., (© 2022 John Wiley & Sons Ltd.)

Published

2023

24. The influence of social cues on timing of animal migrations.

Author

Oestreich WK, Aiu KM, Crowder LB, McKenna MF, Berdahl AM, and Abrahms B

Subjects

Animals, Humans, Cues, Biological Evolution, Animal Migration, Ecosystem

Abstract

Animal migration plays a central role in many ecological and evolutionary processes, yet migratory populations worldwide are increasingly threatened. Adjusting migration timing to match ecosystem phenology is key to survival in dynamic and changing ecosystems, especially in an era of human-induced rapid environmental change. Social cues are increasingly recognized as major components of migratory behaviour, yet a comprehensive understanding of how social cues influence the timing of animal migrations remains elusive. Here, we introduce a framework for assessing the role that social cues, ranging from explicit (for example, active cueing) to implicit (for example, competition), play in animals' temporal migration decisions across a range of scales. By applying this theoretical lens to a systematic review of published literature, we show that a broad range of social cues frequently mediate migration timing at a range of temporal scales and across highly diverse migratory taxa. We further highlight that while rarely documented, several social cue mechanisms (for example, social learning and density dependency) play important adaptive roles in matching migration timing with ecosystem dynamics. Thus, social cues play a fundamental role in migration timing, with potentially widespread ecological consequences and implications for the conservation of migratory species. Furthermore, our analysis establishes a theoretical basis on which to evaluate future findings on the role of both conspecific and interspecific social cues in this intersection of behavioural ecology and global change biology., (© 2022. Springer Nature Limited.)

Published

2022

25. A spatial capture-recapture model for group-living species.

Author

Emmet RL, Augustine BC, Abrahms B, Rich LN, and Gardner B

Subjects

Computer Simulation, Population Density, Population Dynamics, Ecosystem

Abstract

Group living in species can have complex consequences for individuals, populations, and ecosystems. Therefore, estimating group density and size is often essential for understanding population dynamics, interspecific interactions, and conservation needs of group-living species. Spatial capture-recapture (SCR) has been used to model both individual and group density in group-living species, but modeling either individual-level or group-level detection results in different biases due to common characteristics of group-living species, such as highly cohesive movement or variation in group size. Furthermore, no SCR method currently estimates group density, individual density, and group size jointly. Using clustered point processes, we developed a cluster SCR model to estimate group density, individual density, and group size. We compared the model to standard SCR models using both a simulation study and a data set of detections of African wild dogs (Lycaon pictus), a group-living carnivore, on camera traps in northern Botswana. We then tested the model's performance under various scenarios of group movement in a separate simulation study. We found that the cluster SCR model outperformed a standard group-level SCR model when fitted to data generated with varying group sizes, and mostly recovered previous estimates of wild dog group density, individual density, and group size. We also found that the cluster SCR model performs better as individuals' movements become more correlated with their groups' movements. The cluster SCR model offers opportunities to investigate ecological hypotheses relating group size to population dynamics while accounting for cohesive movement behaviors in group-living species., (© 2021 The Ecological Society of America.)

Published

2022

26. An integrated path for spatial capture-recapture and animal movement modeling.

Author

McClintock BT, Abrahms B, Chandler RB, Conn PB, Converse SJ, Emmet RL, Gardner B, Hostetter NJ, and Johnson DS

Subjects

Animals, Population Density, Ecology, Movement

Abstract

Ecologists and conservation biologists increasingly rely on spatial capture-recapture (SCR) and movement modeling to study animal populations. Historically, SCR has focused on population-level processes (e.g., vital rates, abundance, density, and distribution), whereas animal movement modeling has focused on the behavior of individuals (e.g., activity budgets, resource selection, migration). Even though animal movement is clearly a driver of population-level patterns and dynamics, technical and conceptual developments to date have not forged a firm link between the two fields. Instead, movement modeling has typically focused on the individual level without providing a coherent scaling from individual- to population-level processes, whereas SCR has typically focused on the population level while greatly simplifying the movement processes that give rise to the observations underlying these models. In our view, the integration of SCR and animal movement modeling has tremendous potential for allowing ecologists to scale up from individuals to populations and advancing the types of inferences that can be made at the intersection of population, movement, and landscape ecology. Properly accounting for complex animal movement processes can also potentially reduce bias in estimators of population-level parameters, thereby improving inferences that are critical for species conservation and management. This introductory article to the Special Feature reviews recent advances in SCR and animal movement modeling, establishes a common notation, highlights potential advantages of linking individual-level (Lagrangian) movements to population-level (Eulerian) processes, and outlines a general conceptual framework for the integration of movement and SCR models. We then identify important avenues for future research, including key challenges and potential pitfalls in the developments and applications that lie ahead., (© 2021 The Authors. Ecology published by Wiley Periodicals LLC on behalf of Ecological Society of America. This article has been contributed to by US Government employees and their work is in the public domain in the USA.)

Published

2022

27. Blue whales increase feeding rates at fine-scale ocean features.

Author

Fahlbusch JA, Czapanskiy MF, Calambokidis J, Cade DE, Abrahms B, Hazen EL, and Goldbogen JA

Subjects

Animals, Ecosystem, Feeding Behavior, Humans, Movement, Oceans and Seas, Seasons, Balaenoptera

Abstract

Marine predators face the challenge of reliably finding prey that is patchily distributed in space and time. Predators make movement decisions at multiple spatial and temporal scales, yet we have a limited understanding of how habitat selection at multiple scales translates into foraging performance. In the ocean, there is mounting evidence that submesoscale (i.e. less than 100 km) processes drive the formation of dense prey patches that should hypothetically provide feeding hot spots and increase predator foraging success. Here, we integrated environmental remote-sensing with high-resolution animal-borne biologging data to evaluate submesoscale surface current features in relation to the habitat selection and foraging performance of blue whales in the California Current System. Our study revealed a consistent functional relationship in which blue whales disproportionately foraged within dynamic aggregative submesoscale features at both the regional and feeding site scales across seasons, regions and years. Moreover, we found that blue whale feeding rates increased in areas with stronger aggregative features, suggesting that these features indicate areas of higher prey density. The use of fine-scale, dynamic features by foraging blue whales underscores the need to take these features into account when designating critical habitat and may help inform strategies to mitigate the impacts of human activities for the species.

Published

2022

28. Long-term, climate-driven phenological shift in a tropical large carnivore.

Author

Abrahms B, Rafiq K, Jordan NR, and McNutt JW

Subjects

Animals, Datasets as Topic, Ecosystem, Seasons, Temperature, Canidae physiology, Climate Change, Endangered Species

Abstract

Understanding the degree to which animals are shifting their phenology to track optimal conditions as the climate changes is essential to predicting ecological responses to global change. Species at low latitudes or high trophic levels are theoretically expected to exhibit weaker phenological responses than other species, but limited research on tropical systems or on top predators impedes insight into the contexts in which these predictions are upheld. Moreover, a lack of phenological studies on top predators limits understanding of how climate change impacts propagate through entire ecosystems. Using a 30-y dataset on endangered African wild dogs ( Lycaon pictus ), we examined changes in reproductive phenology and temperatures during birthing and denning over time, as well as potential fitness consequences of these changes. We hypothesized that their phenology would shift to track a stable thermal range over time. Data from 60 packs and 141 unique pack-years revealed that wild dogs have delayed parturition by 7 days per decade on average in response to long-term warming. This shift has led to temperatures on birthing dates remaining relatively stable but, contrary to expectation, has led to increased temperatures during denning periods. Increased denning temperatures were associated with reduced reproductive success, suggesting that a continued phenological shift in the species may become maladaptive. Such results indicate that climate-driven shifts could be more widespread in upper trophic levels than previously appreciated, and they extend theoretical understanding of the species traits and environmental contexts in which large phenological shifts can be expected to occur as the climate changes.

Published

2022

29. Ontogenetic shifts from social to experiential learning drive avian migration timing.

Author

Abrahms B, Teitelbaum CS, Mueller T, and Converse SJ

Subjects

Animals, Behavior, Animal, Biological Ontologies, Climate Change, Learning, Seasons, Animal Migration, Birds physiology

Abstract

Migrating animals may benefit from social or experiential learning, yet whether and how these learning processes interact or change over time to produce observed migration patterns remains unexplored. Using 16 years of satellite-tracking data from 105 reintroduced whooping cranes, we reveal an interplay between social and experiential learning in migration timing. Both processes dramatically improved individuals' abilities to dynamically adjust their timing to track environmental conditions along the migration path. However, results revealed an ontogenetic shift in the dominant learning process, whereby subadult birds relied on social information, while mature birds primarily relied on experiential information. These results indicate that the adjustment of migration phenology in response to the environment is a learned skill that depends on both social context and individual age. Assessing how animals successfully learn to time migrations as environmental conditions change is critical for understanding intraspecific differences in migration patterns and for anticipating responses to global change., (© 2021. The Author(s).)

Published

2021

30. Marine heatwave challenges solutions to human-wildlife conflict.

Author

Samhouri JF, Feist BE, Fisher MC, Liu O, Woodman SM, Abrahms B, Forney KA, Hazen EL, Lawson D, Redfern J, and Saez LE

Subjects

Animals, Climate, Conservation of Natural Resources, Ecosystem, Humans, Whales, Animals, Wild, Fisheries

Abstract

Despite the increasing frequency and magnitude of extreme climate events, little is known about how their impacts flow through social and ecological systems or whether management actions can dampen deleterious effects. We examined how the record 2014-2016 Northeast Pacific marine heatwave influenced trade-offs in managing conflict between conservation goals and human activities using a case study on large whale entanglements in the U.S. west coast's most lucrative fishery (the Dungeness crab fishery). We showed that this extreme climate event diminished the power of multiple management strategies to resolve trade-offs between entanglement risk and fishery revenue, transforming near win-win to clear win-lose outcomes (for whales and fishers, respectively). While some actions were more cost-effective than others, there was no silver-bullet strategy to reduce the severity of these trade-offs. Our study highlights how extreme climate events can exacerbate human-wildlife conflict, and emphasizes the need for innovative management and policy interventions that provide ecologically and socially sustainable solutions in an era of rapid environmental change.

Published

2021

31. Body size and digestive system shape resource selection by ungulates: A cross-taxa test of the forage maturation hypothesis.

Author

Esmaeili S, Jesmer BR, Albeke SE, Aikens EO, Schoenecker KA, King SRB, Abrahms B, Buuveibaatar B, Beck JL, Boone RB, Cagnacci F, Chamaillé-Jammes S, Chimeddorj B, Cross PC, Dejid N, Enkhbyar J, Fischhoff IR, Ford AT, Jenks K, Hemami MR, Hennig JD, Ito TY, Kaczensky P, Kauffman MJ, Linnell JDC, Lkhagvasuren B, McEvoy JF, Melzheimer J, Merkle JA, Mueller T, Muntifering J, Mysterud A, Olson KA, Panzacchi M, Payne JC, Pedrotti L, Rauset GR, Rubenstein DI, Sawyer H, Scasta JD, Signer J, Songer M, Stabach JA, Stapleton S, Strand O, Sundaresan SR, Usukhjargal D, Uuganbayar G, Fryxell JM, and Goheen JR

Subjects

Animals, Body Size, Digestive System, Ruminants

Abstract

The forage maturation hypothesis (FMH) states that energy intake for ungulates is maximised when forage biomass is at intermediate levels. Nevertheless, metabolic allometry and different digestive systems suggest that resource selection should vary across ungulate species. By combining GPS relocations with remotely sensed data on forage characteristics and surface water, we quantified the effect of body size and digestive system in determining movements of 30 populations of hindgut fermenters (equids) and ruminants across biomes. Selection for intermediate forage biomass was negatively related to body size, regardless of digestive system. Selection for proximity to surface water was stronger for equids relative to ruminants, regardless of body size. To be more generalisable, we suggest that the FMH explicitly incorporate contingencies in body size and digestive system, with small-bodied ruminants selecting more strongly for potential energy intake, and hindgut fermenters selecting more strongly for surface water., (© 2021 John Wiley & Sons Ltd.)

Published

2021

32. Human-wildlife conflict under climate change.

Author

Abrahms B

Subjects

Animals, Humans, Animals, Wild, Climate Change, Human Activities, Natural Resources

Published

2021

33. Emerging Perspectives on Resource Tracking and Animal Movement Ecology.

Author

Abrahms B, Aikens EO, Armstrong JB, Deacy WW, Kauffman MJ, and Merkle JA

Subjects

Animals, Biodiversity, Movement, Ecology, Ecosystem

Abstract

Resource tracking, where animals increase energy gain by moving to track phenological variation in resources across space, is emerging as a fundamental attribute of animal movement ecology. However, a theoretical framework to understand when and where resource tracking should occur, and how resource tracking should lead to emergent ecological patterns, is lacking. We present a framework that unites concepts from optimal foraging theory and landscape ecology, which can be used to generate and test predictions on how resource dynamics shape animal movement across taxa, systems, and scales. Consideration of the interplay between animal movement and resource dynamics not only advances ecological understanding but can also guide biodiversity conservation in an era of global change., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2021

34. Where did they not go? Considerations for generating pseudo-absences for telemetry-based habitat models.

Author

Hazen EL, Abrahms B, Brodie S, Carroll G, Welch H, and Bograd SJ

Abstract

Background: Habitat suitability models give insight into the ecological drivers of species distributions and are increasingly common in management and conservation planning. Telemetry data can be used in habitat models to describe where animals were present, however this requires the use of presence-only modeling approaches or the generation of 'pseudo-absences' to simulate locations where animals did not go. To highlight considerations for generating pseudo-absences for telemetry-based habitat models, we explored how different methods of pseudo-absence generation affect model performance across species' movement strategies, model types, and environments., Methods: We built habitat models for marine and terrestrial case studies, Northeast Pacific blue whales (Balaenoptera musculus) and African elephants (Loxodonta africana). We tested four pseudo-absence generation methods commonly used in telemetry-based habitat models: (1) background sampling; (2) sampling within a buffer zone around presence locations; (3) correlated random walks beginning at the tag release location; (4) reverse correlated random walks beginning at the last tag location. Habitat models were built using generalised linear mixed models, generalised additive mixed models, and boosted regression trees., Results: We found that the separation in environmental niche space between presences and pseudo-absences was the single most important driver of model explanatory power and predictive skill. This result was consistent across marine and terrestrial habitats, two species with vastly different movement syndromes, and three different model types. The best-performing pseudo-absence method depended on which created the greatest environmental separation: background sampling for blue whales and reverse correlated random walks for elephants. However, despite the fact that models with greater environmental separation performed better according to traditional predictive skill metrics, they did not always produce biologically realistic spatial predictions relative to known distributions., Conclusions: Habitat model performance may be positively biased in cases where pseudo-absences are sampled from environments that are dissimilar to presences. This emphasizes the need to carefully consider spatial extent of the sampling domain and environmental heterogeneity of pseudo-absence samples when developing habitat models, and highlights the importance of scrutinizing spatial predictions to ensure that habitat models are biologically realistic and fit for modeling objectives.

Published

2021

35. Effects of body size on estimation of mammalian area requirements.

Author

Noonan MJ, Fleming CH, Tucker MA, Kays R, Harrison AL, Crofoot MC, Abrahms B, Alberts SC, Ali AH, Altmann J, Antunes PC, Attias N, Belant JL, Beyer DE Jr, Bidner LR, Blaum N, Boone RB, Caillaud D, de Paula RC, de la Torre JA, Dekker J, DePerno CS, Farhadinia M, Fennessy J, Fichtel C, Fischer C, Ford A, Goheen JR, Havmøller RW, Hirsch BT, Hurtado C, Isbell LA, Janssen R, Jeltsch F, Kaczensky P, Kaneko Y, Kappeler P, Katna A, Kauffman M, Koch F, Kulkarni A, LaPoint S, Leimgruber P, Macdonald DW, Markham AC, McMahon L, Mertes K, Moorman CE, Morato RG, Moßbrucker AM, Mourão G, O'Connor D, Oliveira-Santos LGR, Pastorini J, Patterson BD, Rachlow J, Ranglack DH, Reid N, Scantlebury DM, Scott DM, Selva N, Sergiel A, Songer M, Songsasen N, Stabach JA, Stacy-Dawes J, Swingen MB, Thompson JJ, Ullmann W, Vanak AT, Thaker M, Wilson JW, Yamazaki K, Yarnell RW, Zieba F, Zwijacz-Kozica T, Fagan WF, Mueller T, and Calabrese JM

Subjects

Animals, Body Size, Endangered Species, Homing Behavior, Humans, Conservation of Natural Resources, Mammals

Abstract

Accurately quantifying species' area requirements is a prerequisite for effective area-based conservation. This typically involves collecting tracking data on species of interest and then conducting home-range analyses. Problematically, autocorrelation in tracking data can result in space needs being severely underestimated. Based on the previous work, we hypothesized the magnitude of underestimation varies with body mass, a relationship that could have serious conservation implications. To evaluate this hypothesis for terrestrial mammals, we estimated home-range areas with global positioning system (GPS) locations from 757 individuals across 61 globally distributed mammalian species with body masses ranging from 0.4 to 4000 kg. We then applied block cross-validation to quantify bias in empirical home-range estimates. Area requirements of mammals <10 kg were underestimated by a mean approximately15%, and species weighing approximately100 kg were underestimated by approximately50% on average. Thus, we found area estimation was subject to autocorrelation-induced bias that was worse for large species. Combined with the fact that extinction risk increases as body mass increases, the allometric scaling of bias we observed suggests the most threatened species are also likely to be those with the least accurate home-range estimates. As a correction, we tested whether data thinning or autocorrelation-informed home-range estimation minimized the scaling effect of autocorrelation on area estimates. Data thinning required an approximately93% data loss to achieve statistical independence with 95% confidence and was, therefore, not a viable solution. In contrast, autocorrelation-informed home-range estimation resulted in consistently accurate estimates irrespective of mass. When relating body mass to home range size, we detected that correcting for autocorrelation resulted in a scaling exponent significantly >1, meaning the scaling of the relationship changed substantially at the upper end of the mass spectrum., (© 2020 The Authors. Conservation Biology published by Wiley Periodicals LLC on behalf of Society for Conservation Biology.)

Published

2020

36. Memory and resource tracking drive blue whale migrations.

Author

Abrahms B, Hazen EL, Aikens EO, Savoca MS, Goldbogen JA, Bograd SJ, Jacox MG, Irvine LM, Palacios DM, and Mate BR

Subjects

Animals, Balaenoptera psychology, California, Ecosystem, Memory physiology, Movement, Animal Migration physiology, Balaenoptera physiology

Abstract

In terrestrial systems, the green wave hypothesis posits that migrating animals can enhance foraging opportunities by tracking phenological variation in high-quality forage across space (i.e., "resource waves"). To track resource waves, animals may rely on proximate cues and/or memory of long-term average phenologies. Although there is growing evidence of resource tracking in terrestrial migrants, such drivers remain unevaluated in migratory marine megafauna. Here we present a test of the green wave hypothesis in a marine system. We compare 10 years of blue whale movement data with the timing of the spring phytoplankton bloom resulting in increased prey availability in the California Current Ecosystem, allowing us to investigate resource tracking both contemporaneously (response to proximate cues) and based on climatological conditions (memory) during migrations. Blue whales closely tracked the long-term average phenology of the spring bloom, but did not track contemporaneous green-up. In addition, blue whale foraging locations were characterized by low long-term habitat variability and high long-term productivity compared with contemporaneous measurements. Results indicate that memory of long-term average conditions may have a previously underappreciated role in driving migratory movements of long-lived species in marine systems, and suggest that these animals may struggle to respond to rapid deviations from historical mean environmental conditions. Results further highlight that an ecological theory of migration is conserved across marine and terrestrial systems. Understanding the drivers of animal migration is critical for assessing how environmental changes will affect highly mobile fauna at a global scale., Competing Interests: The authors declare no conflict of interest.

Published

2019

37. Mesoscale activity facilitates energy gain in a top predator.

Author

Abrahms B, Scales KL, Hazen EL, Bograd SJ, Schick RS, Robinson PW, and Costa DP

Subjects

Animal Migration, Animals, Diving, Predatory Behavior, Energy Intake, Feeding Behavior, Food Chain, Seals, Earless physiology

Abstract

How animal movement decisions interact with the distribution of resources to shape individual performance is a key question in ecology. However, links between spatial and behavioural ecology and fitness consequences are poorly understood because the outcomes of individual resource selection decisions, such as energy intake, are rarely measured. In the open ocean, mesoscale features (approx. 10-100 km) such as fronts and eddies can aggregate prey and thereby drive the distribution of foraging vertebrates through bottom-up biophysical coupling. These productive features are known to attract predators, yet their role in facilitating energy transfer to top-level consumers is opaque. We investigated the use of mesoscale features by migrating northern elephant seals and quantified the corresponding energetic gains from the seals' foraging patterns at a daily resolution. Migrating elephant seals modified their diving behaviour and selected for mesoscale features when foraging. Daily energy gain increased significantly with increasing mesoscale activity, indicating that the physical environment can influence predator fitness at fine temporal scales. Results show that areas of high mesoscale activity not only attract top predators as foraging hotspots, but also lead to increased energy transfer across trophic levels. Our study provides evidence that the physical environment is an important factor in controlling energy flow to top predators by setting the stage for variation in resource availability. Such understanding is critical for assessing how changes in the environment and resource distribution will affect individual fitness and food web dynamics., (© 2018 The Author(s).)

Published

2018

38. Climate mediates the success of migration strategies in a marine predator.

Author

Abrahms B, Hazen EL, Bograd SJ, Brashares JS, Robinson PW, Scales KL, Crocker DE, and Costa DP

Subjects

Animals, Animal Migration, Climate Change, Seals, Earless

Abstract

Individual behavioural specialisation has far-reaching effects on fitness and population persistence. Theory predicts that unconditional site fidelity, that is fidelity to a site independent of past outcome, provides a fitness advantage in unpredictable environments. However, the benefits of alternative site fidelity strategies driving intraspecific variation remain poorly understood and have not been evaluated in different environmental contexts. We show that contrary to expectation, strong and weak site fidelity strategies in migratory northern elephant seals performed similarly over 10 years, but the success of each strategy varied interannually and was strongly mediated by climate conditions. Strong fidelity facilitated stable energetic rewards and low risk, while weak fidelity facilitated high rewards and high risk. Weak fidelity outperformed strong fidelity in anomalous climate conditions, suggesting that the evolutionary benefits of site fidelity may be upended by increasing environmental variability. We highlight how individual behavioural specialisation may modulate the adaptive capacity of species to climate change., (© 2017 John Wiley & Sons Ltd/CNRS.)

Published

2018

39. Resource partitioning facilitates coexistence in sympatric cetaceans in the California Current.

Author

Fossette S, Abrahms B, Hazen EL, Bograd SJ, Zilliacus KM, Calambokidis J, Burrows JA, Goldbogen JA, Harvey JT, Marinovic B, Tershy B, and Croll DA

Abstract

Resource partitioning is an important process driving habitat use and foraging strategies in sympatric species that potentially compete. Differences in foraging behavior are hypothesized to contribute to species coexistence by facilitating resource partitioning, but little is known on the multiple mechanisms for partitioning that may occur simultaneously. Studies are further limited in the marine environment, where the spatial and temporal distribution of resources is highly dynamic and subsequently difficult to quantify. We investigated potential pathways by which foraging behavior may facilitate resource partitioning in two of the largest co-occurring and closely related species on Earth, blue ( Balaenoptera musculus ) and humpback ( Megaptera novaeangliae ) whales. We integrated multiple long-term datasets (line-transect surveys, whale-watching records, net sampling, stable isotope analysis, and remote-sensing of oceanographic parameters) to compare the diet, phenology, and distribution of the two species during their foraging periods in the highly productive waters of Monterey Bay, California, USA within the California Current Ecosystem. Our long-term study reveals that blue and humpback whales likely facilitate sympatry by partitioning their foraging along three axes: trophic, temporal, and spatial. Blue whales were specialists foraging on krill, predictably targeting a seasonal peak in krill abundance, were present in the bay for an average of 4.7 months, and were spatially restricted at the continental shelf break. In contrast, humpback whales were generalists apparently feeding on a mixed diet of krill and fishes depending on relative abundances, were present in the bay for a more extended period (average of 6.6 months), and had a broader spatial distribution at the shelf break and inshore. Ultimately, competition for common resources can lead to behavioral, morphological, and physiological character displacement between sympatric species. Understanding the mechanisms for species coexistence is both fundamental to maintaining biodiverse ecosystems, and provides insight into the evolutionary drivers of morphological differences in closely related species.

Published

2017

40. Toward a community ecology of landscapes: predicting multiple predator-prey interactions across geographic space.

Author

Schmitz OJ, Miller JRB, Trainor AM, and Abrahms B

Subjects

Animals, Ecology, Ecosystem, Food Chain, Predatory Behavior

Abstract

Community ecology was traditionally an integrative science devoted to studying interactions between species and their abiotic environments in order to predict species' geographic distributions and abundances. Yet for philosophical and methodological reasons, it has become divided into two enterprises: one devoted to local experimentation on species interactions to predict community dynamics; the other devoted to statistical analyses of abiotic and biotic information to describe geographic distribution. Our goal here is to instigate thinking about ways to reconnect the two enterprises and thereby return to a tradition to do integrative science. We focus specifically on the community ecology of predators and prey, which is ripe for integration. This is because there is active, simultaneous interest in experimentally resolving the nature and strength of predator-prey interactions as well as explaining patterns across landscapes and seascapes. We begin by describing a conceptual theory rooted in classical analyses of non-spatial food web modules used to predict species interactions. We show how such modules can be extended to consideration of spatial context using the concept of habitat domain. Habitat domain describes the spatial extent of habitat space that predators and prey use while foraging, which differs from home range, the spatial extent used by an animal to meet all of its daily needs. This conceptual theory can be used to predict how different spatial relations of predators and prey could lead to different emergent multiple predator-prey interactions such as whether predator consumptive or non-consumptive effects should dominate, and whether intraguild predation, predator interference or predator complementarity are expected. We then review the literature on studies of large predator-prey interactions that make conclusions about the nature of multiple predator-prey interactions. This analysis reveals that while many studies provide sufficient information about predator or prey spatial locations, and thus meet necessary conditions of the habitat domain conceptual theory for drawing conclusions about the nature of the predator-prey interactions, several studies do not. We therefore elaborate how modern technology and statistical approaches for animal movement analysis could be used to test the conceptual theory, using experimental or quasi-experimental analyses at landscape scales., (© 2017 by the Ecological Society of America.)

Published

2017

41. Suite of simple metrics reveals common movement syndromes across vertebrate taxa.

Author

Abrahms B, Seidel DP, Dougherty E, Hazen EL, Bograd SJ, Wilson AM, Weldon McNutt J, Costa DP, Blake S, Brashares JS, and Getz WM

Abstract

Background: Because empirical studies of animal movement are most-often site- and species-specific, we lack understanding of the level of consistency in movement patterns across diverse taxa, as well as a framework for quantitatively classifying movement patterns. We aim to address this gap by determining the extent to which statistical signatures of animal movement patterns recur across ecological systems. We assessed a suite of movement metrics derived from GPS trajectories of thirteen marine and terrestrial vertebrate species spanning three taxonomic classes, orders of magnitude in body size, and modes of movement (swimming, flying, walking). Using these metrics, we performed a principal components analysis and cluster analysis to determine if individuals organized into statistically distinct clusters. Finally, to identify and interpret commonalities within clusters, we compared them to computer-simulated idealized movement syndromes representing suites of correlated movement traits observed across taxa (migration, nomadism, territoriality, and central place foraging)., Results: Two principal components explained 70% of the variance among the movement metrics we evaluated across the thirteen species, and were used for the cluster analysis. The resulting analysis revealed four statistically distinct clusters. All simulated individuals of each idealized movement syndrome organized into separate clusters, suggesting that the four clusters are explained by common movement syndrome., Conclusions: Our results offer early indication of widespread recurrent patterns in movement ecology that have consistent statistical signatures, regardless of taxon, body size, mode of movement, or environment. We further show that a simple set of metrics can be used to classify broad-scale movement patterns in disparate vertebrate taxa. Our comparative approach provides a general framework for quantifying and classifying animal movements, and facilitates new inquiries into relationships between movement syndromes and other ecological processes.

Published

2017

42. Conservation policy. Wildlife decline and social conflict.

Author

Brashares JS, Abrahms B, Fiorella KJ, Golden CD, Hojnowski CE, Marsh RA, McCauley DJ, Nuñez TA, Seto K, and Withey L

Subjects

Conflict, Psychological, Crime prevention & control, Crime trends, Employment, Enslavement prevention & control, Human Trafficking prevention & control, Human Trafficking trends, Humans, Conservation of Natural Resources trends, Security Measures trends

Published

2014