Energetics and fear of humans constrain the spatial ecology of pumas

Nickel, Barry; Suraci, Justin P.; Nisi, Anna C.; Wilmers, Christopher C.

doi:10.1073/pnas.2004592118

Cited by 41 publications

(50 citation statements)

References 59 publications

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“…Despite the loss of natural habitat associated with increasing human footprint, agricultural lands and developed areas nonetheless present opportunities for some species through resource subsidies or relaxed predation/competition (Prugh & Sivy, 2020; Sévêque et al, 2020). Increased human footprint is also associated with decreased movement and smaller home ranges for many mammal species (Doherty et al, 2021; Tucker et al, 2018), including large predators such as pumas (Nickel et al, 2021). Thus, higher intensity of use in more heavily modified habitats by species that otherwise tend to avoid human footprint (e.g., pumas and bobcats, Serieys et al, 2021; Suraci et al, 2020) may reflect restricted movement options and thus intensified use of remaining habitat fragments in moderately developed areas.…”

Section: Discussionmentioning

confidence: 99%

Disturbance type and species life history predict mammal responses to humans

Suraci

Gaynor

Allen

et al. 2021

Global Change Biology

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Human activity and land use change impact every landscape on Earth, driving declines in many animal species while benefiting others. Species ecological and life history traits may predict success in human‐dominated landscapes such that only species with “winning” combinations of traits will persist in disturbed environments. However, this link between species traits and successful coexistence with humans remains obscured by the complexity of anthropogenic disturbances and variability among study systems. We compiled detection data for 24 mammal species from 61 populations across North America to quantify the effects of (1) the direct presence of people and (2) the human footprint (landscape modification) on mammal occurrence and activity levels. Thirty‐three percent of mammal species exhibited a net negative response (i.e., reduced occurrence or activity) to increasing human presence and/or footprint across populations, whereas 58% of species were positively associated with increasing disturbance. However, apparent benefits of human presence and footprint tended to decrease or disappear at higher disturbance levels, indicative of thresholds in mammal species’ capacity to tolerate disturbance or exploit human‐dominated landscapes. Species ecological and life history traits were strong predictors of their responses to human footprint, with increasing footprint favoring smaller, less carnivorous, faster‐reproducing species. The positive and negative effects of human presence were distributed more randomly with respect to species trait values, with apparent winners and losers across a range of body sizes and dietary guilds. Differential responses by some species to human presence and human footprint highlight the importance of considering these two forms of human disturbance separately when estimating anthropogenic impacts on wildlife. Our approach provides insights into the complex mechanisms through which human activities shape mammal communities globally, revealing the drivers of the loss of larger predators in human‐modified landscapes.

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Section: Discussionmentioning

confidence: 99%

Disturbance type and species life history predict mammal responses to humans

Suraci

Gaynor

Allen

et al. 2021

Global Change Biology

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“…The anthropogenic covariates considered were (i) housing density and (ii) distance to urban edge. Housing density has been shown to be an important driver of puma movement in our study system, 12,14 and impacts movement differently between the day and night (unpublished data). We calculated housing density using Epanechnikov kernels with a 150 m radius [in houses per sq.km], which is the scale at which housing most strongly impacts puma movement.…”

Section: Reportmentioning

confidence: 73%

“…As such, human threat creates a landscape of fear whereby mountain lions generally avoid human voices [9][10][11] and habitat close to human infrastructure, 12 resulting in increased energy expenditure by mountain lions, 13 reduced vagility, and smaller home ranges. 14 This landscape of fear also has cascading impacts on mountain lion kill rates of deer, 15 plant architecture, 16 and rodent space use. 17 On March 17, this region initiated a shelter-in-place order (SIPO) in response to the COVID-19 pandemic.…”

Section: Resultsmentioning

confidence: 99%

“…In all models, we also included topographic and landscape covariates that previous analyses have shown to be important for puma habitat selection in the Santa Cruz Mountains. 12,14,31,32 Specifically, we included topographic slope, topographic position index (TPI, indicating whether a point is mid-slope or on a valley or ridge), the interaction between slope and TPI, distance to nearest perennial river or stream (National Hydrography Dataset, USGS available at https://www.usgs. gov/core-science-systems/ngp/national-hydrography), and percent vegetation cover.…”

Section: Reportmentioning

confidence: 99%

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COVID-19 suppression of human mobility releases mountain lions from a landscape of fear

2021

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COVID-19 suppression of human mobility releases mountain lions from a landscape of fearHighlights d Under normal circumstances, mountain lions strongly avoid urban areas d Human mobility declined by more than 50% during the COVID-19-associated lockdown d Mountain lions relaxed their fear of the urban edge during the lockdown d Pandemics can alter ecological relationships because of changes in human behavior

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“…The latter has developed rapidly since the demonstration that dynamic body acceleration (DBA) is related to energy expenditure across a range of vertebrates and invertebrates (Halsey et al, 2009; Wilson et al, 2019, 2006). Such measurements have great potential for understanding animal strategies, in particular studying how animals respond to change in food availability (Kokubun et al, 2011), climate (Gudk et al, 2019) and anthropogenic threats or activity (Nickel et al, 2021; Payne et al, 2015; Yorzinski et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Ecological inference using data from accelerometers needs careful protocols

Garde

Wilson

Fell

et al. 2021

Preprint

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Accelerometers in animal-attached tags have proven to be powerful tools in behavioural ecology, being used to determine behaviour and provide proxies for movement-based energy expenditure. Researchers are collecting and archiving data across systems, seasons and device types. However, in order to use data repositories to draw ecological inference, we need to establish the error introduced according to sensor type and position on the study animal and establish protocols for error assessment and minimization.Using laboratory trials, we examine the absolute accuracy of tri-axial accelerometers and determine how inaccuracies impact measurements of dynamic body acceleration (DBA), as the main acceleration-based proxy for energy expenditure. We then examine how tag type and placement affect the acceleration signal in birds using (i) pigeons Columba livia flying in a wind tunnel, with tags mounted simultaneously in two positions, (ii) back- and tail-mounted tags deployed on wild kittiwakes Rissa tridactyla. Finally, we (iii) present a case study where two generations of tag were deployed using different attachment procedures on red-tailed tropicbirds Phaethon rubricauda foraging in different seasons.Bench tests showed that individual acceleration axes required a two-level correction (representing up to 4.3% of the total value) to eliminate measurement error. This resulted in DBA differences of up to 5% between calibrated and uncalibrated tags for humans walking at different speeds. Device position was associated with greater variation in DBA, with upper- and lower back-mounted tags in pigeons varying by 9%, and tail- and back-mounted tags varying by 13% in kittiwakes. Finally, DBA varied by 25% in tropicbirds between seasons, which may be attributable to tag attachment procedures.Accelerometer accuracy, tag placement, and attachment details critically affect the signal amplitude and thereby the ability of the system to detect biologically meaningful phenomena. We propose a simple method to calibrate accelerometers that should be used prior to deployments and archived with resulting data, suggest a way that researchers can assess accuracy in previously collected data, and caution that variable tag placement and attachment can increase sensor noise and even generate trends that have no biological meaning.

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Energetics and fear of humans constrain the spatial ecology of pumas

Cited by 41 publications

References 59 publications

Disturbance type and species life history predict mammal responses to humans

Disturbance type and species life history predict mammal responses to humans

COVID-19 suppression of human mobility releases mountain lions from a landscape of fear

Ecological inference using data from accelerometers needs careful protocols

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