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Merging indigenous and scientific knowledge links climate with the growth of a large migratory caribou population
Gagnon, Catherine A.; Hamel, Sandra; Russell, Don E.; Powell, Todd; Andre, James; Svoboda, Michael Y.; Berteaux, Dominique 2019-12-23 <p>1. Climate change in the Arctic is two to three times faster than anywhere else in the world. It is therefore crucial to understand the effects of weather on keystone arctic species, particularly those such as caribou (Rangifer tarandus) that sustain northern communities. Bridging long-term scientific and indigenous knowledge offers a promising path to achieve this goal, as both types of knowledge may complement one another. 2. We assessed the influence of environmental variables on the spring and fall body condition of caribou from the Porcupine Caribou Herd. This herd ranges in the Yukon and Northwest Territories (Canada) and Alaska (USA), and is the only large North American herd that has not declined since the 2000s. Using observations recorded through an indigenous community-based monitoring program between 2000-2010, we analyzed temporal trends in caribou condition and quantified the effects of weather and critical weather-dependent variables (insect harassment and vegetation growth), on spring (n = 617 individuals) and fall (n =711) caribou condition. 3. Both spring and fall body condition improved from 2000 to 2010, despite a continuous population increase of ca. 3.6% per year. Spring and fall caribou condition were influenced by weather on the winter and spring ranges, particularly snow conditions and spring temperatures. Both snow conditions and spring temperatures improved during our study period, likely contributing to the observed caribou population increase. Insect harassment during the previous summer and the frequency of icing events also influenced caribou condition. 4. Synthesis and applications. Our study first shows how untangling the relative influences of seasonal weather variables allows a much better understanding of variation in seasonal body condition in Rangifer populations. Second, it indicates that a large migratory caribou population can grow and improve body condition in a global context of caribou decline and climate warming, thereby warning against generalizations about the influence of climate on all Rangifer populations. Finally, it testifies how data from indigenous community-based monitoring on a large spatiotemporal scale can remarkably improve ecological understanding of wildlife sustaining human communities. We recommend that management practices promote indigenous community-based ecological monitoring whenever feasible.</p>
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Climate, caribou and human needs linked by analysis of Indigenous and scientific knowledge
Gagnon, Catherine A.; Hamel, Sandra; Russell, Don E.; Andre, James; Buckle, Annie; Haogak, David; Pascal, Jessi; Schafer, Esau; Powell, Todd; Svoboda, Michael Y.; Berteaux, Dominique 2023-01-24 <p><span lang="EN-US">Migratory tundra caribou are ecologically and culturally critical in the circumpolar North. However, they are declining almost everywhere in North America, likely due to natural variation exacerbated by climate change and human activities. Yet, the interconnectedness between climate, caribou, and human well-being has received little attention. To address this gap, we bridged</span><span lang="EN-US"> </span><span lang="EN">Indigenous and scientific knowledge in a single model, using as an example the Porcupine caribou herd social-ecological system. Our analysis, involving </span><span lang="EN-US">688 (fall season) and 616 (spring season) interviews conducted over nine years with 405 (fall season) and 390 (spring season) Indigenous hunters </span><span lang="EN-CA">from nine communities, demonstrates that </span><span lang="EN-US">environmental conditions, </span><span lang="EN-CA">large-scale temporal changes associated with caribou demography, and cultural practices </span><span lang="EN-US">affect hunters’ capacity to meet their needs in caribou. </span><span lang="EN">Our quantitative approach </span><span lang="EN-US">bolsters our understanding of the complex relationships between ecosystems and human welfare in environments exposed to rapid climate change and shows </span><span lang="EN">the benefits of long-term participatory research methods implemented by Indigenous and scientific partners.</span></p> https://creativecommons.org/publicdomain/zero/1.0/
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A mechanistic model of functional response provides new insights into indirect interactions among arctic tundra prey
Beardsell, Andréanne; Gravel, Dominique; Clermont, Jeanne; Berteaux, Dominique; Gauthier, Gilles; Bêty, Joël 2022-03-16 Prey handling processes are considered a dominant mechanism leading to short-term positive indirect effects between prey that share a predator. However, a growing body of research indicates that predators are not necessarily limited by such processes in the wild. Density-dependent changes in predator foraging behavior can also generate positive indirect effects but they are rarely included as explicit functions of prey densities in functional response models. With the aim of untangling proximate mechanisms of species interactions in natural communities and improving our ability to quantify interaction strength, we extended the multi-prey version of the Holling disk equation by including density-dependent changes in predator foraging behavior. Our model, based on species traits and behavior, was inspired by the vertebrate community of the arctic tundra, where the main predator (the arctic fox) is an active forager feeding primarily on cyclic small rodent (lemming) and eggs of various tundra-nesting bird species. Short-term positive indirect effects of lemmings on birds have been documented over the circumpolar Arctic but the underlying mechanisms remain poorly understood. We used a unique data set, containing high-frequency GPS tracking, accelerometer, behavioral, and experimental data to parameterize the multi-prey model, and a 15-year time series of prey densities and bird nesting success to evaluate interaction strength between species. We found that: (i) prey handling processes play a minor role in our system and (ii) changes in arctic fox daily activity budget and distance traveled can partly explain the predation release on birds observed during lemming peaks. These adjustments in predator foraging behavior with respect to the main prey density thus appear as the dominant mechanism leading to positive indirect effects commonly reported among arctic tundra prey. Density-dependent changes in functional response components have been little studied in natural vertebrate communities and deserve more attention to improve our ability to quantify the strength of species interactions.
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Prey availability influences the effect of boldness on reproductive success in a mammalian predator
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Clermont, Jeanne; Couchoux, Charline; Lai, Sandra; Berteaux, Dominique 2023-05-18 <p>Boldness is an important trait in wild populations and among-individual differences can link to individual fitness<span lang="EN-GB">. </span>The strength and direction of relationships between behavioral and life-history traits may however vary according to environmental conditions, where fluctuating selection acting on behavioral traits contributes to the maintenance of personality differences. <span lang="EN-GB">We </span>explored sources of variation in <span lang="EN-GB">Arctic fox (<em>Vulpes</em> <em>lagopus</em>) boldness </span>and <span lang="EN-GB">investigated how temporal variation in the abundance of a main prey (lemmings) influences the relationship between fox boldness and reproductive success. We measured the behavioral reaction of individuals when escaping after handling, as an indicator of their boldness. We obtained 70 measurements from 42 individuals </span>during two years of low lemming abundance and two years of high lemming abundance<span lang="EN-GB"> and assessed fox litter size as an indicator of reproductive success. First, individual characteristics (age, sex, mass) did not affect Arctic fox boldness, while individual identity generated variation in boldness. Next, </span>we found that during years of low lemming density, individuals behaving boldly had more pups than those behaving less boldly, suggesting boldness may provide an advantage when lemmings are scarce by increasing hunting success or allowing access to alternative resources. However, all <span lang="EN-GB">individuals tended to show high levels of boldness when lemming density was high, and all produced large litters. </span>Temporal variation in the abundance of a main prey might therefore influence the relation between boldness and reproductive success of a predator, and if individuals consistently differ in their level of boldness, fluctuating selection could contribute to the maintenance of personality.</p>
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Data from: Movement tactics of a mobile predator in a meta-ecosystem with fluctuating resources: the arctic fox in the High Arctic
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Lai, Sandra; Bêty, Joël; Berteaux, Dominique 2016-10-26 Animal movement is a fundamental process shaping ecosystems at multiple levels, from the fate of individuals to global patterns of biodiversity. The spatio-temporal dynamic of food resources is a major driver of animal movement and generates patterns ranging from range residency to migration and nomadism. Arctic tundra predators face a strongly fluctuating environment marked by cyclic microtine populations, high seasonality, and the potential availability of sea ice, which gives access to marine resources in winter. This type of relatively poor and highly variable environment can promote long-distance movements and resource tracking in mobile species. Here, we investigated the winter movements of the arctic fox, a major tundra predator often described as a seasonal migrant or nomad. We used six years of Argos satellite telemetry data collected on 66 adults from Bylot Island (Nunavut, Canada) tracked during the sea ice period. We hypothesized that long-distance movements would be influenced by spatio-temporal changes in resource availability and individual characteristics. Despite strong annual and seasonal changes in resource abundance and distribution, we found that a majority of individuals remained resident, especially those located in an area characterized by highly predictable pulse resources (goose nesting colony) and abundant cached food items (eggs). Foxes compensated terrestrial food shortage by commuting to the sea ice rather than using long-distance tracking or moving completely onto the sea ice for winter. Individual characteristics also influenced movement patterns: age positively influenced the propensity to engage in nomadism, suggesting older foxes may be driven out of their territories. Our results show how these mammalian predators can adjust their movement patterns to favor range residency despite strong spatio-temporal fluctuations in food resources. Understanding the movement responses of predators to prey dynamics helps identifying the scales at which they work, which is a critical aspect of the functioning and connectivity among meta-ecosystems.
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Cover data of vascular plants, cryptogams, and ground substrates at Alert (Ellesmere Island, Nunavut)
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Desjardins, Émilie; Lai, Sandra; Vézina, François; Tam, Andrew; Berteaux, Dominique 2021 Establishing new ecological baselines and initiating monitoring schemes on Arctic vegetation are critical to monitor, predict, and manage current and future impacts of climate change. We conducted systematic plot-based surveys in the polar desert surrounding Alert (Ellesmere Island, Nunavut) to provide a temporal snapshot of current species diversity and abundance, and to establish a georeferenced baseline with permanent field markers allowing robust re-surveying. A random stratified design was used, based on a habitat map of the study area (ca. 170 km2), to select the location of the vegetation plots. Each vegetation plot corresponded in five 1 m × 1 m quadrats, each located 5 m from a central point and at equal distance from one another. Following the point-intercept method of the International Tundra Experiment, we obtained in each quadrat an index of absolute cover for (1) vascular plants (identified to the species level), (2) cryptogams (identified as biological soil crust, cyanobacteria (blue-green algae), lichen, macrofungus, or moss), and (3) ground substrates (bare soil or rock). In 2018-2019, a total of 264 vegetation plots were surveyed (corresponding to 1,320 m2-quadrats) and among them, 50 vegetation plots (corresponding to 250 1-m2 quadrats) were permanently marked using two 20-cm metal nails hammered into the ground at opposite corners of the quadrats. Vascular plants are described in Desjardins et al. (2021a) whereas data collection methods and techniques are detailed in Desjardins et al. (2021a, 2021b). L'établissement de nouvelles bases de référence écologiques et la mise en place de programmes de suivi de la végétation arctique sont essentiels pour surveiller, prédire et gérer les impacts actuels et futurs des changements climatiques. Nous avons effectué des relevés systématiques par quadrats dans le désert polaire entourant Alert (Nunavut, Canada) pour fournir un portrait actuel de la diversité et de l'abondance des espèces ainsi que pour établir une base de données géoréférencée avec des quadrats marqués de façon permanente permettant un rééchantillonnage rigoureux. Un plan d’échantillonnage aléatoire stratifié, basé sur une carte d'habitat de la zone d'étude (environ 170 km2), a été utilisé pour sélectionner l'emplacement des parcelles de végétation. Chaque parcelle de végétation correspondait à cinq quadrats de 1 m × 1 m, chacun situé à 5 m d'un point central et à égale distance les uns des autres. En suivant la méthode du point d'interception du réseau « International Tundra Experiment », nous avons obtenu dans chaque quadrat un indice de couverture absolue pour (1) les plantes vasculaires (identifiées à l'espèce), (2) les cryptogames (identifiées comme croûte biologique du sol, cyanobactéries (algue bleu-vert), lichen, champignon ou mousse) et (3) les types de substrats (sol nu ou roche). En 2018-2019, 264 parcelles de végétation ont été échantillonnées (correspondant à 1 320 quadrats de 1 m2) et parmi celles-ci, 50 parcelles de végétation (correspondant à 250 quadrats de 1 m2) ont été marquées de façon permanente à l'aide de deux clous métalliques de 20 cm enfoncés dans le sol aux coins opposés des quadrats. La liste des plantes vasculaires est décrite dans Desjardins et al. (2021a) alors que les méthodes et techniques de collecte de données sont détaillées dans Desjardins et al. (2021a, 2021b).

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(Author: Berteaux, Dominique)

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