10 results on '"McInturf, Alexandra G."'
Search Results
2. Spatial Distribution, Temporal Changes, and Knowledge Gaps in Basking Shark (Cetorhinus maximus) Sightings in the California Current Ecosystem
- Author
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McInturf, Alexandra G, Muhling, Barbara, Bizzarro, Joseph J, Fangue, Nann A, Ebert, David A, Caillaud, Damien, and Dewar, Heidi
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Oceanography ,Biological Sciences ,Ecology ,Earth Sciences ,Geology ,species distribution model ,population trend ,schooling behavior ,conservation ,behavioral ecology ,environmental change - Abstract
Among the largest fish species, the basking shark (Cetorhinus maximus) is found circumglobally in temperate and tropical waters. Though historical documents have recorded their presence in the California Current Ecosystem (CCE), basking sharks are now only rarely observed in this part of their range. We compiled recent and historical data from systematic surveys (1962–1997) and other sources (1973–2018) to (i) examine temporal patterns of basking shark sightings in the CCE, and (ii) determine the spatial, temporal, and environmental drivers that have affected basking shark presence and distribution here for the last 50 years. We first calculated variation in basking shark sightings and school size over time. We then generated species distribution models using the systematic survey data and evaluated the performance of these models against the more recent non-systematic sightings data. The sightings records indicated that the number of shark sightings was variable across years, but the number and probability of sightings declined in the mid-1980s. The systematic survey data showed up to nearly 4,000 sharks sighted per year until the 1990s, after which there were no sightings reported. In parallel, there was more than a 50% decline in school size from the 1960s to the 1980s (57.2 to 24.0 individuals per group). During the subsequent decades in the non-systematic data (>1990), less than 60 sharks were sighted per year. There were no schools larger than 10 reported, and the mean school size in the last decade (2010s) was 3.53 individuals per group. Low sea surface temperature and high chlorophyll a concentration increased sightings probability, and prevailing climatic oscillations (El Nino-Southern Oscillation index, North Pacific Gyre Oscillation, Pacific Decadal Oscillation) were also correlated with basking shark presence. Lastly, we observed a significant shift in the seasonality of sightings, from the fall and spring during the systematic survey period to the summer months after the 2000s. We conclude by offering suggestions for future research and conservation efforts; specifically, coordinating the documentation of fisheries mortalities and sightings throughout the Pacific basin would facilitate more robust population estimates and identify sources of mortality. Additionally, monitoring shark fin markets and developing region-specific genetic markers would help ensure that convention on international trade in endangered species (CITES) regulations are being followed.
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- 2022
3. Vectors with autonomy: what distinguishes animal‐mediated nutrient transport from abiotic vectors?
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McInturf, Alexandra G, Pollack, Lea, Yang, Louie H, and Spiegel, Orr
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Biological Sciences ,Ecology ,Nutrition ,Life on Land ,Animals ,Behavior ,Animal ,Birds ,Conservation of Natural Resources ,Ecosystem ,Forests ,Insect Vectors ,Lakes ,Nutrients ,Oceans and Seas ,Rivers ,Time Factors ,Wind ,animal behaviour ,behavioural ecology ,energy flow ,mobile links ,movement ecology ,nutrient cycling ,spatial subsidies ,Evolutionary Biology ,Biological sciences - Abstract
Animal movements are important drivers of nutrient redistribution that can affect primary productivity and biodiversity across various spatial scales. Recent work indicates that incorporating these movements into ecosystem models can enhance our ability to predict the spatio-temporal distribution of nutrients. However, the role of animal behaviour in animal-mediated nutrient transport (i.e. active subsidies) remains under-explored. Here we review the current literature on active subsidies to show how the behaviour of active subsidy agents makes them both ecologically important and qualitatively distinct from abiotic processes (i.e. passive subsidies). We first propose that animal movement patterns can create similar ecological effects (i.e. press and pulse disturbances) in recipient ecosystems, which can be equal in magnitude to or greater than those of passive subsidies. We then highlight three key behavioural features distinguishing active subsidies. First, organisms can transport nutrients counter-directionally to abiotic forces and potential energy gradients (e.g. upstream). Second, unlike passive subsidies, organisms respond to the patterns of nutrients that they generate. Third, animal agents interact with each other. The latter two features can form positive- or negative-feedback loops, creating patterns in space or time that can reinforce nutrient hotspots in places of mass aggregations and/or create lasting impacts within ecosystems. Because human-driven changes can affect both the space-use of active subsidy species and their composition at both population (i.e. individual variation) and community levels (i.e. species interactions), predicting patterns in nutrient flows under future modified environmental conditions depends on understanding the behavioural mechanisms that underlie active subsidies and variation among agents' contributions. We conclude by advocating for the integration of animal behaviour, animal movement data, and individual variation into future conservation efforts in order to provide more accurate and realistic assessments of changing ecosystem function.
- Published
- 2019
4. Use of a hydrodynamic model to examine behavioral response of broadnose sevengill sharks (Notorynchus cepedianus) to estuarine tidal flow
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McInturf, Alexandra G, Steel, Anna E, Buckhorn, Michele, Sandstrom, Philip, Slager, Christina J, Fangue, Nann A, Klimley, A Peter, and Caillaud, Damien
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Life Below Water ,Active tracking ,Estuary ,Movement ecology ,Environmental data ,Ecology ,Zoology ,Fisheries Sciences ,Fisheries - Abstract
Innovative telemetry and biologging technology has increased the amount of available movement data on aquatic species. However, real-time information on the environmental factors influencing animal movements can be logistically challenging to obtain, particularly in habitats where tides and currents vary locally. Hydrodynamic models are capable of simulating complex tidal flow, and may thus offer an alternative method of contextualizing animal movement in coastal habitats. Here we use this tool to examine the influence of tide on the movement of broadnose sevengill sharks (Notorynchus cepedianus) in the San Francisco Bay estuary. Three sharks were actively tracked using acoustic transmitters for 3 to 4 days. We then generated a hydrodynamic model of the estuary and calculated current vectors along each track. We hypothesized that the sharks would adjust their swimming speed and direction depending on current strength when passing through the channel underneath the Golden Gate Bridge. Our results indicate that sharks did tend to follow the current flow in the channel, but their overall displacement did not significantly correlate with tidal amplitude. We conclude that the sharks may respond to environmental factors other than tidal flow, altering their movement at a finer scale than initially considered. Overall, this suggests that hydrodynamic simulation models can be used to visualize and quantify environmental factors that may affect movement patterns in aquatic organisms. We recommend future studies combine these models with other biologging techniques to measure energy expenditure at a finer spatial scale.
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- 2019
5. Behavioral response of megafauna to boat collision measured via animal-borne camera and IMU.
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Chapple, Taylor K., Cade, David E., Goldbogen, Jeremy, Massett, Nick, Payne, Nicholas, and McInturf, Alexandra G.
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WATER use ,TERRITORIAL waters ,WATER depth ,ACCELERATION (Mechanics) ,UNITS of measurement - Abstract
Overlap between marine megafauna and maritime activities is a topic of global concern. Basking sharks (Cetorhinus maximus; CM) are listed as Globally Endangered under the IUCN, though reported sightings appear to be increasing in Ireland. While such trends in the region are welcome, increasing spatiotemporal overlap between CM and numerous water users poses an increased risk of boat strikes to the animals. To demonstrate the risk and impact of boat strikes on marine megafauna, we present camera-enabled animal-borne inertial measurement unit (IMU) data from a non-lethal boat strike on a CM within a proposed National Marine Park in Ireland. We tagged a ~7-m female CM in County Kerry, Ireland, which was struck by a boat ~6 h after tag deployment. Comparison of pre-strike data with 4 h of video and ~7.5 h of IMU data following the boat strike provides critical insight into the animal’s response. While the CM reacted momentarily with an increase in activity and swam to the seafloor, it quickly reduced its overall activity (i.e., overall dynamic body acceleration, tailbeat cycles, tailbeat amplitude, and vertical velocity) for the remainder of the deployment. Notably, the animal also ceased feeding for the duration of the video and headed towards deep offshore waters, which is in stark contrast to the pre-strike period where the animal was consistently observed feeding along the surface in shallow coastal water. This work provides insight into a CM’s response to acute injury and highlights the need for appropriate protections to mitigate risks for marine megafauna. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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6. Advancing the ecological narrative: documentation of broadnose sevengill sharks (Notorynchus cepedianus) in South Puget Sound, Washington, USA.
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Schulte, Jessica M., Personius, Ethan M., Lowry, Dayv, Hillier, Lisa, McInturf, Alexandra G., and Chapple, Taylor K.
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SHARKS ,TOP predators ,ESTUARIES ,DOCUMENTATION ,MARINE ecology - Abstract
The broadnose sevengill shark (Notorynchus cepedianus) is a large, apex predator found in temperate waters around the world. Yet data on their distribution are limited, with reports of species occurrence typically restricted to specific bays or estuaries where they have been historically observed in high seasonal abundances. The Puget Sound is located in the southern portion of the Salish Sea, a large estuary spanning the border between northwestern Washington state, USA and southwestern British Columbia, Canada, and serves as an economic, cultural, and ecological hub. Until recently, there was only one verified record of broadnose sevengill sharks in the Salish Sea and none in the Puget Sound. However, our recent multi-agency collaborative effort revealed the presence of adult and sub-adult broadnose sevengill sharks in South Puget Sound, extending their previously known range hundreds of kilometers and into a new ecosystem. This work represents the first evidence of a significant presence of these apex sharks within the Salish Sea. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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7. A Multi-scale Investigation of Fish Response to Environmental Change
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McInturf, Alexandra G
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Aquatic sciences ,Animal sciences ,Ecology - Abstract
The impacts of climate change and anthropogenic disturbance are pervasive throughout ecosystems. Yet particularly in aquatic and marine systems, animal responses to the resulting environmental changes can be difficult to determine, which inhibits appropriate management strategies. Conservation efforts are often based on research that examines the effect of stressors or human-induced impacts on a single species and/or scale. However, this approach can be too narrowly focused. Species do not exist in isolation, and there are many potential drivers of their survivorship and behavior that extend beyond the individual or population. Particularly for mobile species, such as many fishes, population dynamics can be strongly influenced by species interactions, individual movements within a habitat, or changes in habitat suitability. As a result, the impacts of environmental change can be highly complex or even counter-intuitive, particularly in locations where these changes are occurring rapidly. Among these, California hosts a variety of aquatic and marine habitats that have been dramatically modified by human activity over the last century. These ecosystems now face further alteration due to a changing climate. Consequently, there is growing concern about how species will respond to additional stressors, such as increasing water temperatures. Our ability to forecast these effects is becoming increasingly important, because while many endemic fishes are already heavily managed, some populations are continuing to decline. The potential consequences of these declines can be dire, affecting ecological communities as well as human populations that rely on fish for sustenance. However, the mechanisms underlying patterns of fish presence and survival are multifaceted and remain undetermined in many cases, preventing a reevaluation of conservation efforts. To address this, my dissertation demonstrates the value of a more holistic perspective on organismal response to environmental change. Focusing on species that are threatened or data deficient in California waters, I use select case studies to examine fish responses to environmental changes at multiple scales, including fish physiology, behavior, and habitat use. Chapter 1 is based in the Sacramento-San Joaquin River Delta of California’s Central Valley. Here, increased mortality of outmigrating juvenile salmon has been correlated to warming water temperature. It has been assumed that reduced survivorship is due to salmon thermal physiology. Yet emerging laboratory studies suggest that these salmon populations are relatively thermally robust. Instead, I test the hypothesis that decreases in salmon survivorship are due to increased activity of non-native predators. My results suggest that major predators of salmon in the Delta are more thermally adapted to warmer temperatures, increasing the possibility of their threat to juvenile salmon in light of global warming. This indicates that an understanding of fundamental thermal physiology can be useful in predicting predator-prey dynamics; however, I also show that such an approach is highly dependent on the physiological metric employed, and it is more effective for some species than others. Regardless, given that the Delta is a highly modified ecosystem, managers could hypothetically improve juvenile salmon survivorship by adjusting water flow, and therefore temperature, along primary outmigration routes based on predator thermal preferences. Chapter 2 scales up to consider fish behavioral response to current flows in the San Francisco Bay Estuary. In estuarine habitats, seasonal and daily hydrological variance is affected by human activity, such as dredging and coastal wetland development, and rising sea levels due to global warming. However, assessing fish responses to hydrological patterns is logistically challenging, limiting our ability to predict how future changes will impact the behavior of local populations. In this chapter, I explore the use of hydrodynamic models for examining the influence of tidal flow in the San Francisco Bay Estuary on broadnose sevengill sharks (Notorynchus cepedianus). Combining acoustic tracking data with these models, I find evidence that sharks swim in and out of the bay with most of the ebb and flood tides, presumably to move in the most energetically efficient manner. However, this movement was not universal, nor was it dependent on the strength of the tide. This suggests that there may be other variables shaping sevengill shark behavior in this habitat, such as prey availability, which offsets the energetic cost of moving against the tide. Taken together, my results demonstrate that tidal movement is not the sole driver of sevengill shark behavior, but this species will likely be susceptible to potential hydrological changes in the future. Chapter 3 examines environmental impacts at the largest scale, using a spatial modeling approach to determine population-level trends and habitat use in a large, highly migratory species: the basking shark. Historically targeted globally for their liver oil, fins, and meat, basking sharks were classified as globally endangered in 2019. While they seem to be responding well to protective measures in some parts of their range, there appears to be no sign of recovery in the Eastern North Pacific population. However, evaluating the status of this population is hindered by multiple data gaps. It has not been determined whether variation in shark sightings over time is due to changes in population size or the effect of environmental change on basking shark distribution. To fill these gaps, I compile recent and historical data to describe variation in basking shark sightings and school size over time in the California Current Ecosystem (CCE). I also build species distribution models using general additive mixed models to determine the environmental factors that may affect their distribution and sightings probability. My results suggest that the number and probability of sightings declined in the mid-1980s, as did the size of schools reported. Simultaneously, there was a shift in sighting seasonality, from fall and spring to summer starting in the 2000s. The species distribution models also revealed that sightings probability increased with low sea surface temperature and high chlorophyll a concentration, and was correlated with larger-scale climatic oscillations. Based on these analyses and previous studies, I conclude that the decline in sightings after the 1980s most likely emerged because of a decrease in the population following a century of culling and overfishing. This was perhaps exacerbated by an Allee effect based on the simultaneous decrease in group size. Furthermore, there is a high probability that the basking sharks that remain in the CCE will be affected by a combination of changing sea surface temperatures and shifting prey fields in the future, though the degree to which this will shift their spatial or temporal distribution is unknown. To better inform management of the CCE basking shark population, there should be more coordinated documentation of fisheries mortalities and sightings to inform population estimates and track potential changes in habitat use. I also advocate for improved monitoring of shark fin markets to ensure existing conservation regulations are being followed. In conclusion, climate change and increasing anthropogenic activity are rapidly altering California’s aquatic and marine ecosystems, rendering conservation more difficult. My dissertation contributes to a large body of evidence highlighting numerous threats, from warming temperatures to habitat alteration, that are affecting species directly and ecosystem interactions more broadly. Together, these chapters show that species responses to potential threats will vary depending on environmental variables, animal behavior, and community interactions. It is critical to consider each of these levels of influence when predicting how populations will fare with environmental change. In turn, this broader understanding will improve dynamic management strategies for threatened species facing an uncertain future.
- Published
- 2021
8. In hot water? Assessing the link between fundamental thermal physiology and predation of juvenile Chinook salmon
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McInturf, Alexandra G., primary, Zillig, Ken W., additional, Cook, Katherine, additional, Fukumoto, Jacqueline, additional, Jones, Anna, additional, Patterson, Emily, additional, Cocherell, Dennis E., additional, Michel, Cyril J., additional, Caillaud, Damien, additional, and Fangue, Nann A., additional
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- 2022
- Full Text
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9. Spatial Distribution, Temporal Changes, and Knowledge Gaps in Basking Shark (Cetorhinus maximus) Sightings in the California Current Ecosystem
- Author
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McInturf, Alexandra G., primary, Muhling, Barbara, additional, Bizzarro, Joseph J., additional, Fangue, Nann A., additional, Ebert, David A., additional, Caillaud, Damien, additional, and Dewar, Heidi, additional
- Published
- 2022
- Full Text
- View/download PDF
10. Plastic ingestion by marine fish is widespread and increasing
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Savoca, Matthew S., primary, McInturf, Alexandra G., additional, and Hazen, Elliott L., additional
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- 2021
- Full Text
- View/download PDF
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