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Landscape Ecology

, Volume 34, Issue 11, pp 2523–2539 | Cite as

Climate, competition and weather conditions drive vertical displacement and habitat use of an alpine ungulate in a highly topographic landscape

  • Ivar HerfindalEmail author
  • Pia Anderwald
  • Flurin Filli
  • Seraina Campell Andri
  • Thomas Rempfler
Research Article

Abstract

Context

Many species experience ecosystem changes due to alterations in climate or interspecific interactions. Animals’ optimal use of landscapes involves adjusting spatial displacement and habitat use according to weather or climate, however, competitive interactions may affect such behavioural responses. Species in alpine landscapes are already at their upper altitudinal range, which can limit behavioural response to ecosystem changes.

Objectives

We investigated how ibex’s use of habitat and altitude was affected by weather, climate, and intra- and interspecific competition in an alpine landscape in Switzerland.

Methods

We combined data from GPS-collared ibex with data on temperature and precipitation, habitat and altitude, and abundance estimates of ibex, chamois, and red deer within the study area. We modelled how the temporal dynamics of habitat and altitude use by ibex was modified by weather, ungulate abundance, and their interactions.

Results

Short- and long-term weather conditions affected ibex’s use of landscape throughout the year as expected based on its ecology, with particularly strong effects of temperature during spring and summer. During spring and autumn, ibex used higher altitudes and less grassland when red deer abundance was high and ibex abundance low. The influence of weather and climate on how ibex used the landscape was only weakly affected by interspecific competition.

Conclusions

Our results suggest that the way that ibex use the landscape is affected by environmental conditions and intra- and interspecific interactions. These factors seem to have additive effects on ibex behaviour.

Keywords

Alpine ibex Capra ibex Chamois Red deer Elevation Habitat Species interactions Swiss Alps 

Notes

Acknowledgements

We would like to thank all Swiss National Park rangers for conducting the visual observations of animals and carrying out all the work related to capturing and marking them. Numerous interns contributed sighting records of marked individuals. We would also thank three anonymous referees and the editor for comments on a previous version. IH was partly funded from the Research Council of Norway through its Centres of Excellence funding scheme, Project No. 223257, and the Project SUSTAIN, Project No. 244647.

References

  1. Abderhalden W (2005) Spatial behaviour and sexual segregation in the Alpine ibex Capra ibex ibex. Nationalpark-Forschung in der Schweiz 92:1–181Google Scholar
  2. Albon SD, Langvatn R (1992) Plant phenology and the benefits of migration in a temperate ungulate. Oikos 65:502–513Google Scholar
  3. Anderwald P, Haller RM, Filli F (2016) Heterogeneity in primary productivity influences competitive interactions between red deer and alpine chamois. PLoS ONE 11:e0146458PubMedPubMedCentralGoogle Scholar
  4. Anderwald P, Herfindal I, Haller RM, Risch AC, Schütz M, Schweiger AK, Filli F (2015) Influence of migratory ungulate management on competitive interactions with resident species in a protected area. Ecosphere 6:228Google Scholar
  5. Apollonio M, Andersen R, Putman R (2010) European ungulates and their management in the 21st century. Cambridge University Press, CambridgeGoogle Scholar
  6. Bjørneraas K, Solberg EJ, Herfindal I, Rolandsen CM, Tremblay J, Sæther B, Eriksen R, Astrup R (2011) Moose habitat use at multiple temporal scales in a human-altered landscape. Wildl Biol 17:44–54Google Scholar
  7. Bolker BM, Brooks ME, Clark CJ, Geange SW, Poulsen JR, Stevens MHH, White JSS (2009) Generalized linear mixed models: a practical guide for ecology and evolution. Trends Ecol Evol 24:127–135PubMedGoogle Scholar
  8. Bunnefeld N, Börger L, van Moorter B, Rolandsen CM, Dettki H, Solberg EJ, Ericsson G (2011) A model-driven approach to quantify migration patterns: individual, regional and yearly differences. J Anim Ecol 80:466–476PubMedGoogle Scholar
  9. Büntgen U, Greuter L, Bollmann K, Jenny H, Liebhold A, Galván JD, Stenseth NC, Andrew C, Mysterud A (2017) Elevational range shifts in four mountain ungulate species from the Swiss Alps. Ecosphere 8:e01761Google Scholar
  10. Büntgen U, Liebhold A, Jenny H, Mysterud A, Egli S, Nievergelt D, Stenseth NC, Bollmann K (2014) European springtime temperature synchronises ibex horn growth across the eastern Swiss Alps. Ecol Lett 17:303–313PubMedGoogle Scholar
  11. Côté SD, Rooney TP, Tremblay J, Dussault C, Waller DM (2004) Ecological impacts of deer overabundance. Annu Rev Ecol Evol Syst 35:113–147Google Scholar
  12. Debeffe L, Rivrud IM, Meisingset EL, Mysterud A (2019) Sex-specific differences in spring and autumn migration in a northern large herbivore. Sci Rep 9:6137PubMedPubMedCentralGoogle Scholar
  13. Deinum B (1984) Chemical composition and nutritive value of herbage in relation to climate. In: Riley H, Skjelvåg AO (eds) The impact of climate on grass production and quality. The Norwegian state agricultural research stations, Norway, pp 338–350Google Scholar
  14. Dirnböck T, Essl F, Rabitsch W (2011) Disproportional risk for habitat loss of high-altitude endemic species under climate change. Glob Change Biol 17:990–996Google Scholar
  15. Ferretti F, Corazza M, Campana I, Pietrocini V, Brunetti C, Scornavacca D, Lovari S (2015) Competition between wild herbivores: reintroduced red deer and Apennine chamois. Behav Ecol 26:550–559Google Scholar
  16. Ferretti F, Sforzi A, Lovari S (2011) Behavioural interference between ungulate species: roe are not on velvet with fallow deer. Behav Ecol Sociobiol 65:875–887Google Scholar
  17. Filli F, Suter W (eds) (2006) Ungulate research in the Swiss National Park. Nationalpark-Forschung in der Schweiz 93. Parc Naziunal Svizzer, Zernes, SwitzerlandGoogle Scholar
  18. Fretwell SD, Lucas HL (1969) On territorial behavior and other factors influencing habitat distribution in birds. Acta Biotheor 19:16–26Google Scholar
  19. Garel M, Cugnasse J, Gaillard J, Loison A, Santosa Y, Maublanc M (2005) Effect of observer experience on the monitoring of a mouflon population. Acta Theriol 50:109–114Google Scholar
  20. Haller R (2006) Spatial distribution of ungulates in the Swiss National Park—evaluation of surveys and analysis methods and comparison with census results. Nationalpark-Forschung in der Schweiz 93:45–78Google Scholar
  21. Haller RM (2011) Integratives Geoinformationsmanagement in der Schutzgebietsforschung—Räumliche Genauigkeit als Schlüsselelement des Wissenstransfers. Nationalpark-Forschung in der Schweiz 95:1–281Google Scholar
  22. Hansen BB, Aanes R, Herfindal I, Kohler J, Sæther B (2011) Climate, icing, and wild arctic reindeer: past relationships and future prospects. Ecology 92:1917–1923PubMedGoogle Scholar
  23. Hansen BB, Aanes R, Herfindal I, Sæther B, Henriksen S (2009) Winter habitat-space use in a large arctic herbivore facing contrasting forage abundance. Polar Biol 32:971–984Google Scholar
  24. Herfindal I (2013) Changes in use of altitudes of male and female Swiss ibex. Cratschla 3(13):24–25Google Scholar
  25. Herfindal I, Lande US, Solberg EJ, Rolandsen CM, Roer O, Wam HK (2017) Weather affects temporal niche partitioning between moose and livestock. Wildl Biol 2017:00275Google Scholar
  26. Herfindal I, Sæther B, Solberg EJ, Andersen R, Høgda KA (2006) Population characteristics predict responses in moose body mass to temporal variation in the environment. J Anim Ecol 75:1110–1118PubMedGoogle Scholar
  27. Hofmann RR (1989) Evolutionary steps of ecophysiological adaptation and diversification of ruminants: a comparative view of their digestive system. Oecologia 78:443–457PubMedGoogle Scholar
  28. Jonasson S, Bryant JP, Chapin FS III, Andersson M (1986) Plant phenols and nutrients in relation to variations in climate and rodent grazing. Am Nat 128:394–408Google Scholar
  29. Lande US, Herfindal I, Willebrand T, Moa PF, Storaas T (2014) Landscape characteristics explain large-scale variation in demographic traits in forest grouse. Landscape Ecol 29:127–139Google Scholar
  30. Langvatn R, Albon SD, Burkey T, Clutton-Brock TH (1996) Climate, plant phenology and variation in age of first reproduction in a temperate herbivore. J Anim Ecol 65:653–670Google Scholar
  31. Largo E, Gaillard J, Festa-Bianchet M, Toïgo C, Bassano B, Cortot H, Farny G, Lequette B, Gauthier D, Martinot J (2008) Can ground counts reliably monitor ibex Capra ibex populations. Wildl Biol 14:489–499Google Scholar
  32. Latham J (1999) Interspecific interactions of ungulates in European forests: an overview. For Ecol Manag 120:13–21Google Scholar
  33. Lotz A (ed) (2006) Alpine habitat diversity HABITALP—project report 2002–2006. EU community initiative INTERREG III B alpine space programme. Nationalpark Berchtesgaden, BerchtesgadenGoogle Scholar
  34. Luo Z, Jiang Z, Tang S (2015) Impacts of climate change on distributions and diversity of ungulates on the Tibetan Plateau. Ecol Appl 25:24–38PubMedGoogle Scholar
  35. Marchand P, Garel M, Bourgoin G, Dubray D, Maillard D, Loison A (2015a) Coupling scale-specific habitat selection and activity reveals sex-specific food/cover trade-offs in a large herbivore. Anim Behav 102:169–187Google Scholar
  36. Marchand P, Garel M, Bourgoin G, Dubray D, Maillard D, Loison A (2015b) Sex-specific adjustments in habitat selection contribute to buffer mouflon against summer conditions. Behav Ecol 26:472–482Google Scholar
  37. Mårell A, Hofgaard A, Danell K (2006) Nutrient dynamics of reindeer forage species along snowmelt gradients at different ecological scales. Basic Appl Ecol 7:13–30Google Scholar
  38. Mason TH, Brivio F, Stephens PA, Apollonio M, Grignolio S (2017) The behavioral trade-off between thermoregulation and foraging in a heat-sensitive species. Behav Ecol 28:908–918Google Scholar
  39. Mason THE, Stephens PA, Apollonio M, Willis SG (2014) Predicting potential responses to future climate in an alpine ungulate: interspecific interactions exceed climate effects. Glob Change Biol 20:3872–3882Google Scholar
  40. Melin M, Matala J, Mehtätalo L, Tiilikainen R, Tikkanen O, Maltamo M, Pusenius J, Packalen P (2014) Moose (Alces alces) reacts to high summer temperatures by utilizing thermal shelters in boreal forests: an analysis based on airborne laser scanning of the canopy structure at moose locations. Glob Change Biol 20:1115–1125Google Scholar
  41. Milner-Gulland EJ, Fryxell JM, Sinclair ARE (eds) (2011) Animal migration. A synthesis. Oxford University Press, OxfordGoogle Scholar
  42. Mutanga O, Prins HH, Skidmore AK, Wieren S, Huizing H, Grant R, Peel M, Biggs H (2004) Explaining grass-nutrient patterns in a savanna rangeland of southern Africa. J Biogeogr 31:819–829Google Scholar
  43. Mysterud A, Austrheim G (2013) Lasting effects of snow accumulation on summer performance of large herbivores in alpine ecosystems may not last. J Anim Ecol 83:712–719Google Scholar
  44. Mysterud A, Bjørnsen BH, Østbye E (1997) Effects of snow depth on food and habitat selection by roe deer Capreolus capreolus along an altitudinal gradient in south-central Norway. Wildl Biol 3:27–33Google Scholar
  45. Mysterud A, Iversen C, Austrheim G (2007) Effects of density, season and weather on use of an altitudinal gradient by sheep. Appl Anim Behav Sci 108:104–113Google Scholar
  46. Mysterud A, Langvatn R, Yoccoz NG, Stenseth NC (2001a) Plant phenology, migration and geographical variation in body weight of a large herbivore: the effect of a variable topography. J Anim Ecol 70:915–923Google Scholar
  47. Mysterud A, Østbye E (1995) Bed-site selection by European roe deer (Capreolus capreolus) in southern Norway during winter. Can J Zool 73:924–932Google Scholar
  48. Mysterud A, Pérez-Barbería FJ, Gordon IJ (2001b) The effect of season, sex and feeding style on home range area versus body mass scaling in temperate ruminants. Oecologia 127:30–39PubMedGoogle Scholar
  49. Nievergelt B (1967) Die Zusammensetzung der Gruppen beim Alpensteinbock. Z Saugetierkd 32:129–144Google Scholar
  50. Parrini F, Grignolio S, Luccarini S, Bassano B, Apollonio M (2003) Spatial behaviour of adult male Alpine ibex Capra ibex ibex in the Gran Paradiso National Park, Italy. Acta Theriol 48:411–423Google Scholar
  51. Pettorelli N, Mysterud A, Yoccoz NG, Langvatn R, Stenseth NC (2005) Importance of climatological downscaling and plant phenology for red deer in heterogeneous landscapes. Proc R Soc Lond B 272:2357–2364Google Scholar
  52. Putman R (1996) Competition and resource partitioning in temperate ungulate assemblies. Chapman & Hall, LondonGoogle Scholar
  53. Redjadj C, Darmon G, Maillard D, Chevrier T, Bastianelli D, Verheyden H, Loison A, Saïd S (2014) Intra- and interspecific differences in diet quality and composition in a large herbivore community. PLoS ONE 9:e84756PubMedPubMedCentralGoogle Scholar
  54. Rolandsen CM, Solberg EJ, Sæther B, van Moorter B, Herfindal I, Bjørneraas K (2017) On fitness and partial migration in a large herbivore—migrant females have higher reproductive performance than resident females. Oikos 126:547–555Google Scholar
  55. Ruckstuhl KE, Neuhaus P (2002) Sexual segregation in ungulates: a comparative test of three hypotheses. Biol Rev 77:77–96PubMedGoogle Scholar
  56. Sæther B, Engen S, Filli F, Aanes R, Schröder W, Andersen R (2002) Stochastic population dynamics of an introduced Swiss population of the ibex. Ecology 83:3457–3465Google Scholar
  57. Sæther B, Sutherland WJ, Engen S (2004) Climate influences on avian population dynamics. Adv Ecol Res 35:185–209Google Scholar
  58. Schaefer JA, Bergman CM, Luttich SN (2000) Site fidelity of female caribou at multiple spatial scales. Landscape Ecol 15:731–739Google Scholar
  59. Schweiger AK, Schütz M, Anderwald P, Schaepman ME, Kneubühler M, Haller R, Risch AC (2015) Foraging ecology of three sympatric ungulate species—Behavioural and resource maps indicate differences between chamois, ibex and red deer. Mov Ecol 3:209Google Scholar
  60. Sinclair ARE, Norton-Griffiths M (1982) Does competition or facilitation regulate migrant ungulate populations in the Serengeti? A test of hypotheses. Oecologia 53:364–369PubMedGoogle Scholar
  61. Stewart KM, Bowyer RT, Dick BL, Johnson BK, Kie JG (2005) Density-dependent effects on physical condition and reproduction in North American elk: an experimental test. Oecologia 143:85–93PubMedGoogle Scholar
  62. Stewart KM, Bowyer RT, Kie JG, Cimon NJ, Johnson BK (2002) Temporospatial distributions of elk, mule deer, and cattle: resource partitioning and competitive displacement. J Mamm 83:229–244Google Scholar
  63. Travis JMJ, Delgado M, Bocedi G, Baguette M, Bartoń K, Bonte D, Boulangeat I, Hodgson JA, Kubisch A, Penteriani V, Saastamoinen M, Stevens VM, Bullock JM (2013) Dispersal and species’ responses to climate change. Oikos 112:1532–1540Google Scholar
  64. Tremblay J, Solberg EJ, Sæther B, Heim M (2007) Fidelity to calving areas in moose (Alces alces) in the absence of natural predators. Can J Zool 85:902–908Google Scholar
  65. Valeix M, Loveridge AJ, Chamaillé-Jammes S, Davidson Z, Murindagomo F, Fritz H, Macdonald DW (2009) Behavioral adjustments of African herbivores to predation risk by lions: spatiotemporal variations influence habitat use. Ecology 90:23–30PubMedGoogle Scholar
  66. van Beest FM, McLoughlin PD, Mysterud A, Brook RK (2016) Functional responses in habitat selection are density dependent in a large herbivore. Ecography 39:515–523Google Scholar
  67. van de Pol M, Vindenes Y, Sæther B, Engen S, Ens BJ, Oosterbeek K, Tinbergen JM (2010) Effects of climate change and variability on population dynamics in a long-lived shorebird. Ecology 91:1192–1204PubMedGoogle Scholar
  68. Wam HK, Herfindal I (2018) Subtle foodscape displacement of a native ungulate by free-ranging livestock in a forest agroecosystem. Ecosphere 9:e02280Google Scholar
  69. White RG (1983) Foraging patterns and their multiplier effects on productivity of northern ungulates. Oikos 40:377–384Google Scholar
  70. Wiens JD, Anthony RG, Forsman ED (2014) Competitive interactions and resource partitioning between northern spotted owls and barred owls in western Oregon. Wildl Monogr 185:1–50Google Scholar
  71. Wiseman PA, Carling MD, Byers JA (2006) Frequency and correlates of birth-site fidelity in pronghorns (Antilocapra americana). J Mamm 87:312–317Google Scholar
  72. Wood SN (2006) Generalized additive models: an introduction with R. Chapman and Hall/CRC, New YorkGoogle Scholar
  73. Zeng Z, Beck PSA, Wang T, Skidmore AK, Song Y, Gong H, Prins HHT (2010) Effects of plant phenology and solar radiation on seasonal movement of golden takin in the Qinling Mountains, China. J Mamm 91:92–100Google Scholar
  74. Zoller H (1995) Vegetationskarte des Schweizerischen Nationalparks. Nationalpark-Forschung in der Schweiz 85:1–108Google Scholar
  75. Zuur AF, Ieno EN, Walker NJ, Saveliev AA, Smith GM (2009) Mixed effects models and extensions in ecology with R. Springer, New YorkGoogle Scholar

Copyright information

© Springer Nature B.V. 2019

Authors and Affiliations

  1. 1.Department of Biology, Centre for Biodiversity DynamicsNorwegian University of Science and TechnologyTrondheimNorway
  2. 2.Swiss National ParkZernezSwitzerland

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