East or west: the energetic cost of being a gray whale and the consequence of losing energy to disturbance

Villegas‐Amtmann, Stella; Schwarz, Lisa; Gailey, Glenn; Sychenko, O.; Costa, Daniel P.

doi:10.3354/esr00843

Cited by 40 publications

(52 citation statements)

References 40 publications

(27 reference statements)

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“…Telemetry data can provide information on the patterns of repeated exposure for specific individuals (Costa et al., ; Falcone et al., ; Jones et al., ; Madsen et al., ; Pirotta, New, & Marcoux, ), and photographic identification (e.g., Calambokidis, Barlow, Ford, Chandler, & Douglas, ) can be used to estimate exposure risks for regularly monitored populations (Christiansen, Bertulli, Rasmussen, & Lusseau, ; Pirotta, Thompson, Cheney, Donovan, & Lusseau, ). In alternative, some studies examined the consequences of exposing all individuals in a population to the same amount of disturbance (Braithwaite, Meeuwig, & Hipsey, ; New et al., ; Villegas‐Amtmann, Schwarz, Gailey, Sychenko, & Costa, ; Villegas‐Amtmann, Schwarz, Sumich, & Costa, ).…”

Section: Estimating Levels Of Exposure In the Populationmentioning

confidence: 99%

“…They have been used to assess the responses of harbor porpoises ( Phocoena phocoena ) to wind farm developments (Brandt, Diederichs, Betke, & Nehls, ; Nabe‐Nielsen, Sibly, Tougaard, Teilmann, & Sveegaard, ; Nabe‐Nielsen et al., ), of Blainville's beaked whales ( Mesoplodon densirostris ) to sonar (Moretti et al., ; Tyack et al., ), and of bottlenose dolphins ( Tursiops truncatus ) to boat presence (Pirotta, Merchant, Thompson, Barton, & Lusseau, ). In the absence of empirical data, behavioral responses have been extrapolated from better‐studied species or assumed, often in terms of the number of lost foraging days (King et al., ; New et al., ; Villegas‐Amtmann et al., , ). Most studies (e.g., Williams, Lusseau, & Hammond, ) have evaluated the decrease in energy intake due to the observed behavioral responses.…”

Section: Effect Of Exposure On Physiology and Behaviormentioning

confidence: 99%

“…() examined the relation between foraging activity and energy stores (estimated from changes in buoyancy) of female southern elephant seals ( Mirounga leonina ) over the course of a foraging trip. Other applications have inferred changes in energy stores from models of foraging activity that either treat energy explicitly using a bioenergetic approach (Beltran, Testa, & Burns, ; Christiansen & Lusseau, ; Farmer, Noren, Fougères, Machernis, & Baker, ; McHuron, Costa, Schwarz, & Mangel, ; McHuron, Mangel, Schwarz, & Costa, ; Noren, ; Pirotta, Mangel, et al., ; Villegas‐Amtmann et al., , ) or use an arbitrarily scaled energy metric that represents an underlying motivational state (Nabe‐Nielsen et al., , ; New, Harwood, et al., ; Pirotta, Harwood, et al., ; Pirotta, New, Harwood, & Lusseau, ). Although technologies that can measure the morphometrics of individuals remotely may make it easier to estimate changes in body condition directly (e.g., Christiansen, Dujon, Sprogis, Arnould, & Bejder, ; Miller, Best, Perryman, Baumgartner, & Moore, ), extensive health assessment in cetaceans will probably remain limited to a few closely monitored coastal populations, due to logistical constraints (Wells et al., ).…”

Section: Effect Of Behavioral and Physiological Changes On Healthmentioning

confidence: 99%

“…In the absence of a direct estimate of calf survival, Christiansen and Lusseau () used the fetal length of minke whales ( Balaenoptera acutorostrata ) as a proxy, and investigated how fetal length was associated with female body condition (Christiansen, Víkingsson, Rasmussen, & Lusseau, ). All other PCoD studies of marine mammals have assumed a simple relationship between various health metrics and vital rates (McHuron, Costa, et al., ; Nabe‐Nielsen et al., , ; Pirotta, Mangel, et al., ; Villegas‐Amtmann et al., , ).…”

Section: Effect Of Variations In Health On Vital Ratesmentioning

confidence: 99%

“…Some PCoD applications developed IBMs that simulate individuals moving, accessing prey, and accumulating energy stores to sustain survival and reproduction (New, Harwood, et al., ; Pirotta, Harwood, et al., ; Pirotta et al., ; Villegas‐Amtmann et al., ). However, only three studies (Nabe‐Nielsen et al., , ; Villegas‐Amtmann et al., ) have used IBMs to predict the dynamics of a population over time. Although IBMs require considerable data, they are extremely flexible.…”

Section: Modeling the Effect Of Vital Rates On Population Dynamicsmentioning

confidence: 99%

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Understanding the population consequences of disturbance

Pirotta

Booth²,

Costa

et al. 2018

Ecology and Evolution

194

217

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Managing the nonlethal effects of disturbance on wildlife populations has been a long‐term goal for decision makers, managers, and ecologists, and assessment of these effects is currently required by European Union and United States legislation. However, robust assessment of these effects is challenging. The management of human activities that have nonlethal effects on wildlife is a specific example of a fundamental ecological problem: how to understand the population‐level consequences of changes in the behavior or physiology of individual animals that are caused by external stressors. In this study, we review recent applications of a conceptual framework for assessing and predicting these consequences for marine mammal populations. We explore the range of models that can be used to formalize the approach and we identify critical research gaps. We also provide a decision tree that can be used to select the most appropriate model structure given the available data. Synthesis and applications: The implementation of this framework has moved the focus of discussion of the management of nonlethal disturbances on marine mammal populations away from a rhetorical debate about defining negligible impact and toward a quantitative understanding of long‐term population‐level effects. Here we demonstrate the framework's general applicability to other marine and terrestrial systems and show how it can support integrated modeling of the proximate and ultimate mechanisms that regulate trait‐mediated, indirect interactions in ecological communities, that is, the nonconsumptive effects of a predator or stressor on a species' behavior, physiology, or life history.

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Section: Estimating Levels Of Exposure In the Populationmentioning

confidence: 99%

Section: Effect Of Exposure On Physiology and Behaviormentioning

confidence: 99%

Section: Effect Of Behavioral and Physiological Changes On Healthmentioning

confidence: 99%

Section: Effect Of Variations In Health On Vital Ratesmentioning

confidence: 99%

Section: Modeling the Effect Of Vital Rates On Population Dynamicsmentioning

confidence: 99%

See 3 more Smart Citations

Understanding the population consequences of disturbance

Pirotta

Booth²,

Costa

et al. 2018

Ecology and Evolution

194

217

View full text Add to dashboard Cite

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Longer migration not necessarily the costliest strategy for migrating humpback whales

Riekkola

Andrews‐Goff

Friedlaender

et al. 2020

Aquatic Conservation

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Long‐distance migration is a demanding physical activity, and how well animals manage the associated costs will have important implications for their fitness. The Oceania humpback whale (Megaptera novaeangliae) population is recovering from past exploitation markedly slower than the neighbouring east Australian whales. The reasons for this are unknown, although higher energetic costs of longer migratory distances could be a possible explanation. Due to their fully aquatic lives, studying the energy expenditure of these large animals requires methods that do not rely on capturing the animal, such as bioenergetic models. A state‐space model was fitted to satellite data to infer behavioural states for southern migrating whales. Travel speeds and behavioural states were used in a bioenergetic model to estimate the energetic cost of the migration phase. Relative differences in average duration, distance, and energetic costs were compared between migratory routes and distances. Total energy used during migration was a trade‐off between cost of transport (determined by travel speed) and daily maintenance (determined by daily basal metabolic costs). Oceania whales migrating to the Amundsen and Bellingshausen Seas travelled fastest and furthest, 15 and 21% further than whales migrating to the d'Urville Sea (east Australian whales) and Ross Sea, respectively. Therefore, they had the highest cost of transport, 25 and 85% higher than for d'Urville Sea and Ross Sea whales, respectively. However, energy saved in terms of daily maintenance by using fewer days to complete a longer migration resulted in only a 6–7% increase in total energetic cost. The results highlight that travelling further does not necessarily translate into an increase in total energy expenditure for migratory whales, since they can compensate for longer distance by travelling faster. Further research on the energetics of different whale populations could provide insight into the productivity of Southern Ocean feeding regions and help understand the environmental and anthropogenic effects on the whales' energy budgets.

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Important areas for cetaceans in Russian Far East waters

Filatova

Hoyt

Burdin

et al. 2022

Aquatic Conservation

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1. Cetacean species are highly mobile, most of them regularly travelling over long distances, thereby presenting complex obstacles to their conservation.Identification of their critical habitats, specifically those parts of a cetacean's range that are essential for day-to-day survival and for maintaining a healthy population growth rate, is necessary for their effective protection.2. This study presents a summary of the data on cetacean sightings during surveys that covered substantial parts of the Russian Far East coastal waters from the Okhotsk Sea to Chukotka in order to determine important areas for particular cetacean species. Sixteen cetacean species were registered during the surveys, and for 12 of them with sufficient numbers of sightings, zones with maximum sighting rates were identified. 3. Only 13% of all cetacean sightings and 22% of sightings of protected species occurred within marine protected areas (MPAs). The highest sighting rates for protected species were concentrated off north-eastern Sakhalin Island, in the Shantar Area, in Anadyr Gulf, in Kresta Bay and in the waters off eastern Chukotka. The analysis of the distribution patterns of various cetacean species in Russian Far East seas provides a solid base for future conservation planning. Lack of specific MPAs for protection of cetaceans and associated biodiversity hinders marine conservation in Russian Far East seas. 4. The study highlights the specific zones important for various cetacean species and suggests the extension of some existing MPAs and the creation of new MPAs for future spatial habitat protection measures. K E Y W O R D S biodiversity, critical habitat, dolphins, important marine mammal areas, marine protected areas, whales 1 | INTRODUCTION Cetacean species are highly mobile, most of them regularly travelling over long distances, thereby presenting complex obstacles to their conservation. Spatial protection of the entire home range of foraging toothed whales, much less migrating baleen whales, is impractical.There are, however, strategies to address this problem. The starting point is the identification of critical habitats, specifically those parts of a cetacean's range that are essential for day-to-day survival during specific seasons, as well as for maintaining a healthy population growth rate (Hoyt, 2011). Various criteria have been proposed for defining critical habitats for cetaceans, such as their importance for

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East or west: the energetic cost of being a gray whale and the consequence of losing energy to disturbance

Cited by 40 publications

References 40 publications

Understanding the population consequences of disturbance

Understanding the population consequences of disturbance

Longer migration not necessarily the costliest strategy for migrating humpback whales

Important areas for cetaceans in Russian Far East waters

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