Using miniaturized GPS archival tags to assess home range features of a small plunge-diving bird: the European Kingfisher (<i>Alcedo atthis</i>)

Raphaël Musseau; Melina Bastianelli; Clementine Bely; Céline Rousselle; Olivier Dehorter

doi:10.1186/s40657-021-00267-4

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Research | Open Access

Using miniaturized GPS archival tags to assess home range features of a small plunge-diving bird: the European Kingfisher (Alcedo atthis)

Raphaël Musseau^¹

(

), Melina Bastianelli^¹, Clementine Bely^¹, Céline Rousselle^¹, Olivier Dehorter^²

BioSphère Environnement, 52 quai de l'Estuaire, 17120, Mortagne-sur-Gironde, France

Centre de Recherches sur la Biologie des Populations d'Oiseaux, UMR 7204 CNRS MNHN SU‒CESCO: Centre d'Ecologie et des Sciences de la Conservation, Muséum National d'Histoire Naturelle, 43 rue Buffon, case postale 135, 75005, Paris, France

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Abstract

Background

The European Kingfisher (Alcedo atthis) is a small plunge-diving bird, today considered a species of conservation concern in Europe given its rapid population decline observed across the continent. We implemented a pilot study aimed at providing first data allowing to: (1) assess home range features of the European Kingfisher for populations with unevenly distributed feeding habitats; (2) define conservation implications for habitats exploited by such populations; and (3) evaluate possibilities for developing GPS tracking schemes dedicated to home range studies for this species that could be possibly applied to other small plunge-diving birds.

Methods

In 2018 and 2019, we equipped 16 breeding European Kingfishers sampled within the marshes of the Gironde Estuary (France), with miniaturized and waterproof GPS archival tags deployed with leg-loop harnesses (total equipment mass = 1.4 g; average bird mass = 40.18 ± 1.12 g).

Results

On average, we collected 35.31 ± 6.66 locations usable for analyses, without a significant effect on bird body condition (n = 13 tags retrieved). Data analyses highlighted rather limited home ranges exploited by birds (average = 2.50 ± 0.55 ha), composed on average by 2.78 ± 0.40 location nuclei. Our results also underscore: (1) a rather important home range fragmentation index (0.36 ± 0.08); and (2) the use by birds of different types of small wetlands (wet ditches, small ponds or small waterholes), often exploited in addition to habitats encompassing nest locations.

Conclusions

Our study reveals interesting GPS tracking possibilities for small plunge-diving birds such as the European Kingfisher. For this species, today classified as vulnerable in Europe, our results underline the importance of developing conservation and ecological restoration policies for wetland networks that would integrate small wetlands particularly sensitive to global change.

Keywords

GPS tracking Habitat connectivity Small wetlands Waterbirds Wetland ecological networks

References

Adams J, Scott D, McKechnie S, Blackwell G, Shaffer SA, Moller H. Effects of geolocation archival tags on reproduction and adult body mass of sooty shearwaters (Puffinus griseus). New Zealand J Zool Online. 2009;36: 355-66.

Crossref Google Scholar

BirdLife International. Birds in the European Union: a status assessment. BirdLife International: Wageningen; 2004.

BirdLife International. European red list of birds. Luxembourg: Office for Official Publications of the European Communities. 2015. https://www.iucn.org/downloads/redlist___birdlife_publication_web.pdf. Accessed 8 June 2021.

BirdLife International. Species factsheet: Alcedo atthis. 2021. http://datazone.birdlife.org/species/factsheet/common-kingfisher-alcedo-atthis/text. Accessed 8 June 2021.

BirdLife International. Alcedo euryzona (amended version of 2016 assessment). The IUCN Red list of threatened species 2018. . Accessed 8 June 2021. https://doi.org/10.2305/IUCN.UK.2018-2.RLTS.T22726971A125574893.en. Accessed 8 June 2021.

Crossref

Bonnington C, Weaver D, Fanning E. The habitat preference of four kingfisher species along a branch of the Kilombero River, southern Tanzania. Afr J Ecol. 2007;46: 424-7.

Crossref Google Scholar

Brooks DJ, Dunn E, Gillmor R, Hollom PAD, Hudson R, Nicholson EM, et al. Alcedo atthis—Kingfisher. In: Cramp S, editor., et al., Handbook of the birds of Europe, the middle east and north Africa. The birds of the western Palearctic. Terns to woodpeckers, vol. 4. Oxford: Oxford University Press; 1985. p. 711-23.

Campos F, Fernández A, Gutiérrez-Corchero F, Martín-Santos F, Santos P. Diet of the Eurasian kingfisher (Alcedo atthis) in northern Spain. Folia Zool. 2000;49: 115-21.

Google Scholar

Canty A, Ripley BD. Boot: Bootstrap R (S-Plus) Functions. R package, version 1.3-28. 2021. https://cran.r-project.org/web/packages/boot/index.html. Accessed 8 June 2021.

Demongin L. Identification guide to birds in the hand. Brit Birds. 2016;109: 553-5.

Google Scholar

Efron B. Bootstrap methods: another look at the jackknife. Ann Stat. 1979;7: 1-26.

Crossref Google Scholar

Efron B. Better bootstrap confidence intervals. J Am Stat Assoc. 1987;82: 171-85.

Crossref Google Scholar

Efron B, Tibshirani RJ. An introduction to the bootstrap. Monographs on statistics and applied probability. No. 57. London: Chapman and Hall; 1993.https://doi.org/10.1007/978-1-4899-4541-9

Crossref

Fijn RC, de Jong J, Courtens W, Verstraete H, Stienen EWM, Poot MJM. GPS-tracking and colony observations reveal variation in offshore habitat use and foraging ecology of breeding Sandwich Terns. J Sea Res. 2017;127: 203-11.

Crossref Google Scholar

Fraser KC, Shave A, Savage A, Ritchie A, Bell K, Siegrist J, et al. Determining fine-scale migratory connectivity and habitat selection for a migratory songbird by using new GPS technology. J Avian Biol. 2016;48: 339-45.

Crossref Google Scholar

Gibbs JP. Importance of small wetlands for the persistence of local populations of wetland-associated animals. Wetlands. 1993;13: 25-31.

Crossref Google Scholar

Hallworth M, Marra P. Miniaturized GPS tags identify non-breeding territories of a small breeding migratory songbird. Sci Rep. 2015;5: 11069.

Crossref Google Scholar

Hamel NJ, Parrish JK, Conquest LL. Effects of tagging on behavior, provisioning, and reproduction in the Common Murre (Uria aalge), a diving seabird. Auk. 2004;121: 1161-71.

Crossref Google Scholar

Hefting MM, van den Heuvel RN, Verhoeven JTA. Wetlands in agricultural landscapes for nitrogen attenuation and biodiversity enhancement: opportunities and limitations. Ecol Eng. 2013;56: 5-13.

Crossref Google Scholar

Hothorn T, Hornik K, van de Wiel MA, Zeileis A. Implementing a class of permutation tests: the coin package. J Stat Softw. 2008;28: 1-23.

Crossref Google Scholar

Hürner H, Libois R. Étude par radiopistage de la territorialité chez le Martin-pêcheur (Alcedo atthis): cas de deux mâles voisins. Aves. 2005;42: 135-41.

Google Scholar

Kaiser J. An exact and a Monte Carlo proposal to the Fisher-Pitman permutation tests for paired replicates and for independent samples. Stata J. 2007;7: 402-12.

Crossref Google Scholar

Kenward RE. A manual for wildlife radio tagging. London, UK: Academic Press; 2001.

Kenward RE, Clarke RT, Hodder KH, Walls SS. Density and linkage estimators of home range: nearest-neighbor clustering defines multinuclear cores. Ecology. 2001;82: 1905-20.

Crossref Google Scholar

Kenward RE, Walls SS, South AB, Casey NM. Ranges 8 for the analysis of tracking of location data. Wareham: Anatrack Ltd; 2008.

Kesler DC. Non-permanent radiotelemetry leg harness for small birds. J Wildlife Manage. 2011;75: 467-71.

Crossref Google Scholar

Meadows BS. Kingfisher numbers and stream pollution. Ibis. 1972;114: 443.

Google Scholar

Melly BL, Gama PT, Schael DM. Spatial patterns in small wetland systems: identifying and prioritising wetlands most at risk from environmental and anthropogenic impacts. Wetlands Ecol Manage. 2018;26: 1001-13.

Crossref Google Scholar

Peris SJ, Rodriguez R. Some factors related to distribution by breeding Kingfisher (Alcedo atthis L.). Ekol Pol. 1996;44: 31-8.

Google Scholar

Preacher KJ, Selig JP. Advantages of Monte Carlo confidence intervals for indirect effects. Commun Methods Measures. 2012;6: 77-98.

Crossref Google Scholar

R Core Team. R: a language and environment for statistical computing. R Foundation for Statistical Computing. 2020.

Rappole JH, Tipton AR. New harness design for attachment of radio transmitters to small passerines. J Field Ornithol. 1991;62: 335-7.

Google Scholar

Semlitsch RD, Bodie JR. Are small, isolated wetlands expendable? Conserv Biol. 1998;12: 1129-33.https://doi.org/10.1046/j.1523-1739.1998.98166.x

Crossref

Seward A, Taylor RC, Perrow MR, Berridge RJ, Bowgen KM, Dodd S, et al. Effect of GPS tagging on behaviour and marine distribution of breeding Arctic Terns Sterna paradisaea. Ibis. 2021;163: 197-212.

Crossref Google Scholar

Soanes LM, Bright JA, Brodin G, Mukhida F, Green JA. Tracking a small seabird: first records of foraging movements in the Sooty Tern Onychoprion fuscatus. Mar Ornithol. 2015;43: 235-9.

Google Scholar

Silverman BW. Density estimation for statistics and data analysis. London: Chapman and Hall; 1993.

Spiegel CS, Berlin AM, Gilbert AT, Gray CO, Montevecchi WA, Stenhouse IJ, et al. Determining fine scale use and movement patterns of diving bird species in federal waters of the mid-Atlantic United States using satellite telemetry. Sterling (VA): U.S. Department of the Interior, Bureau of Ocean Energy Management. OCS Study BOEM 2017-069. 2017. https://tethys.pnnl.gov/sites/default/files/publications/Spiegel-et-al-2017-BOEM.pdf. Accessed 8 June 2021.

Svensson L. Identification guide to European Passerines. 4th ed. Thetford: British Trust for Ornithology; 1992.

Tomkiewicz SM, Fuller MR, Kie JG, Bates KK. Global positioning system and associated technologies in animal behaviour and ecological research. Philos T Roy Soc b. 2010;365: 2163-76.

Crossref Google Scholar

Tucker GM, Heath MF. Birds in Europe: their conservation status. BirdLife Conservation Series No. 3. Cambridge: BirdLife International; 1994.

Vilches A, Miranda R, Arizaga J, Galicia D. Habitat selection by breeding Common Kingfishers (Alcedo atthis L. ) in rivers from Northern Iberia. Ann Limnol Int J Lim. 2012;48: 289-94.

Crossref Google Scholar

Worton BJ. Kernel methods for estimating the utilization distribution in home-range studies. Ecology. 1989;70: 164-8.

Crossref Google Scholar

Avian Research

Volume 12 Issue 1,
January 2021

Article number: 30

DOI: 10.1186/s40657-021-00267-4

Cite this article:

Musseau R, Bastianelli M, Bely C, et al. Using miniaturized GPS archival tags to assess home range features of a small plunge-diving bird: the European Kingfisher (Alcedo atthis). Avian Research, 2021, 12(1): 30. https://doi.org/10.1186/s40657-021-00267-4

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Received: 07 December 2020

Accepted: 05 June 2021

Published: 10 June 2021

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