Habitat use and movements of a large dragonfly (Odonata: <i>Anax imperator</i>) in a pond network

Minot, Marceau; Besnard, Aurélien; Husté, Aurélie

doi:10.1111/fwb.13632

Cited by 7 publications

(5 citation statements)

References 82 publications

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“…Anax imperator populations sampled in the Normandy region in France had a low level of genetic differentiation (i.e., F ST -values all below 0.03) compared to previous studies on European odonates at a local or regional scale (i.e., F ST up to 0.08, 0.10, 0.24 and 0.28 for Leucorrhinia dubia Vander Linden 1825, Coenagrion scitulum Rambur 1842, C. mercuriale, respectively) [45,[82][83][84]. Such results confirm the high mobility of A. imperator [85] and its efficient dispersal between ponds at the regional scale [54]. However, at the European scale, a moderate level of genetic differentiation was found between populations.…”

Section: Discussionsupporting

confidence: 84%

“…Mature adults present a territorial behaviour but are also very mobile around their mating sites. Movements of individuals have been recorded over few kilometers only, whereas this species is expected to undertake flights on much longer distances [54]. However, lack of information on longdistance dispersal events of Anax imperator can be explained by the difficulty to track insects during long periods with available capture-mark-recapture techniques.…”

Section: Introductionmentioning

confidence: 99%

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Genetic Diversity and Structure of Anax imperator Leach, 1815 Populations (Odonata: Aeshnidae) in Ponds at Regional and European Scales

Minot

Husté

2022

Diversity

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Anthropogenic activities cause loss and fragmentation of natural habitats and have strong effects on population maintenance by increasing their isolation. Pond ecosystems are scattered waterbodies that can interact as a network connected by dispersal events of freshwater organisms. Identifying local genetic differentiations and understanding how gene flow occurs across these networks is essential to prevent risks associated with environmental perturbations. This study aimed to investigate genetic diversity and structure of Anax imperator Leach, 1815 populations at both regional and European scales using seven microsatellites markers. Seven populations of A. imperator were sampled in northwestern France and four populations were sampled in Italy (Sicily), Czech Republic, Switzerland and United Kingdom (U.K.). French populations presented a low genetic differentiation indicating a high gene flow and confirming dispersal events of this species between ponds at regional scale. No pattern of isolation by distance was found at the European scale. The populations presented a low genetic differentiation and no pattern of isolation by distance, suggesting historical or current movements of individuals. Only the U.K. population presented a significant genetic differentiation from other European populations, suggesting that the English Channel might act as a barrier to gene flow for A. imperator. However, Bayesian analysis showed that some dispersal events could occur between the U.K. and France (Normandy), probably facilitated by prevailing winds.

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Section: Discussionsupporting

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Genetic Diversity and Structure of Anax imperator Leach, 1815 Populations (Odonata: Aeshnidae) in Ponds at Regional and European Scales

Minot

Husté

2022

Diversity

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“…Data on survival probability are crucial for demographic modeling (Carey, 1993). The estimated survival probability in A. junius was similar to that reported for the congeneric A. imperator surveyed with conventional capture-mark-recapture in Northwestern France (Minot et al, 2020). Our results show that HSV improved the estimates of survival probability in both species.…”

Section: Implications Of Improving Survival Estimatessupporting

confidence: 80%

“…The model accounts for imperfect detection, gives estimates of the survival and resighting probabilities, and tests how the latter are determined by intrinsic factors such as age, body size, and extrinsic factors such as the weather (Kéry & Schaub, 2012). In odonates, many studies have used CJS to estimate rates of recapture and survival (Cordero-Rivera et al, 2019;Khelifa et al, 2019;Macagno et al, 2008;Minot et al, 2020;Outomuro et al, 2016: Stoks, 2001b).…”

Section: Cormack-jolly-seber Model (Cjs)mentioning

confidence: 99%

Integrating high‐speed videos in capture‐mark‐recapture studies of insects

Khelifa

Mahdjoub

M’Gonigle

et al. 2021

Ecology and Evolution

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Capture–mark–recapture (CMR) studies have been used extensively in ecology and evolution. While it is feasible to apply CMR in some animals, it is considerably more challenging in small fast‐moving species such as insects. In these groups, low recapture rates can bias estimates of demographic parameters, thereby handicapping effective analysis and management of wild populations. Here, we use high‐speed videos (HSV) to capture two large dragonfly species, Anax junius and Rhionaeschna multicolor , that rarely land and, thus, are particularly challenging for CMR studies. We test whether HSV, compared to conventional “eye” observations, increases the “resighting” rates and, consequently, improves estimates of both survival rates and the effects of demographic covariates on survival. We show that the use of HSV increases the number of resights by 64% in A. junius and 48% in R. multicolor . HSV improved our estimates of resighting and survival probability which were either under‐ or overestimated with the conventional observations. Including HSV improved credible intervals for resighting rate and survival probability by 190% and 130% in A. junius and R. multicolor , respectively. Hence, it has the potential to open the door to a wide range of research possibilities on species that are traditionally difficult to monitor with distance sampling, including within insects and birds.

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“…The distance at which the probability of dispersal was 0.5 was used as an indicator of the dispersal ability of the species under analysis (Borthagaray, Cunillera-Montcusí, Bou, Tornero, et al, 2023); Supplementary material 2). We defined 7 different dispersal abilities ranging from 0.001km, which would represent organisms with very limited movement capacity (e.g., Incagnone et al 2015), to 10km, which would represent organisms able to cover large distances across the waterscape (e.g., Figuerola & Green, 2002;Minot et al, 2020) including intermediate dispersal ranges (i.e. 0.1, 0.5, 1, 2, 5km).…”

Section: Dispersal Abilitiesmentioning

confidence: 99%

Fall of giants: European diversity resistance to waterscape degradation and its potential continental drivers

Cunillera-Montcusí,

Borthagaray,

Bou

et al. 2024

Preprint

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Aquatic landscapes, or waterscapes, face severe threats from human activities propelling their deterioration. Waterscape degradation represents a main driver of the current diversity crisis, although its long-term consequences are difficult to quantify. In addition, the understanding of the potential effects of waterscape degradation on biodiversity at large spatial scales, such as biomes and continents, remains limited. In this work, we explore the potential trends in diversity decay in response to waterscape degradation across Europe to provide a first answer to these main threads. We reconstructed the European waterscape based on available satellite data and simulated diversity patterns using a coalescent metacommunity model run for several European ecoregions and considering nine dispersal abilities. Subsequently, we generated a gradient of waterscape degradation by systematically removing a percentage of available habitat and recalculating diversity metrics. For each ecoregion, dispersal ability, and degradation level we obtained a theoretical gamma diversity value. We synthesized the captured diversity decay trends in two parameters: the proportional decay rate and the collapsing rate, which respectively inform about the speed of diversity loss and its acceleration as waterscape degradation progresses. Finally, we mapped these parameters across Europe and related them with ecoregion structural descriptors (i.e. geographic location, water cover, connectivity, and size). Through this exercise, we could identify ecoregions sensitivities and their continental variation based on their diversity decay parameters. Connectivity and water cover emerged as primary descriptors of diversity decay, with more heterogeneous ecoregions generally exhibiting greater resistance to waterscape degradation. Our study provides a first order approximation to an urgently needed information: the continental-scale consequences of waterscape degradation for biodiversity. This data has the potential to improve conservation practices and facilitate the integration of innovative approaches in management, thereby enhancing our understanding of the consequences posed by one of the principal threats to freshwater diversity.

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Habitat use and movements of a large dragonfly (Odonata: Anax imperator) in a pond network

Cited by 7 publications

References 82 publications

Genetic Diversity and Structure of Anax imperator Leach, 1815 Populations (Odonata: Aeshnidae) in Ponds at Regional and European Scales

Genetic Diversity and Structure of Anax imperator Leach, 1815 Populations (Odonata: Aeshnidae) in Ponds at Regional and European Scales

Integrating high‐speed videos in capture‐mark‐recapture studies of insects

Fall of giants: European diversity resistance to waterscape degradation and its potential continental drivers

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