Winandy, Laurane ; Université de Liège - ULiège > Département de Biologie, Ecologie et Evolution > Biologie du comportement - Ethologie et psychologie animale
Cote, Julien
Di Gesu, Lucie
Pellerin, Felix
Trochet, Audrey
Legrand, Delphine
Language :
English
Title :
Local predation risk and matrix permeability interact to shape movement strategy
BaguetteM. et al. 2012. Evolutionary ecology of dispersal in fragmented landscape. – In: Clobert, J. et al. (eds), Dispersal ecology and evolution. Oxford Univ. Press, pp. 381–391.
BainesC. B. et al. 2014. The interactive effects of competition and predation risk on dispersal in an insect. – Biol. Lett.10: 20140287.
BainesC. B. et al. 2015. Dispersal depends on body condition and predation risk in the semi-aquatic insect, Notonecta undulata. – Ecol. Evol.5: 2307–2316.
BeckerC. G. et al. 2007. Habitat split and the global decline of amphibians. – Science318: 1775–1777.
BestionE. et al. 2014. Maternal exposure to predator scents: offspring phenotypic adjustment and dispersal. – Proc. R. Soc. B281: 20140701.
BestionE. et al. 2015. Dispersal response to climate change: scaling down to intraspecific variation. – Ecol. Lett.18: 1226–1233.
BonteD.DahirelM. 2017. Dispersal: a central and independent trait in life history. – Oikos126: 472–479.
BonteD. et al. 2012. Costs of dispersal. – Biol. Rev. 87: 290–312.
BowlerD. E.BentonT. G. 2005. Causes and consequences of animal dispersal strategies: relating individual behaviour to spatial dynamics. – Biol. Rev. 80: 205–225.
BrownG. P. et al. 2006. Toad on the road: use of roads as dispersal corridors by cane toads (Bufo marinus) at an invasion front in tropical Australia. – Biol. Conserv.133: 88–94.
CayuelaH. et al. 2017. Intensive vehicle traffic impacts morphology and endocrine stress response in a threatened amphibian. – Oryx51: 182–188.
CheptouP.-O. et al. 2017. Adaptation to fragmentation: evolutionary dynamics driven by human influences. – Phil. Trans. R. Soc. B372: 20160037.
ChoiI. et al. 2003. Morphometric relationships of take-off speed in anuran amphibians. – J. Exp. Zool. Part A299: 99–102.
ClineB. B.Hunter JrM. L. 2014. Different open-canopy vegetation types affect matrix permeability for a dispersing forest amphibian. – J. Appl. Ecol.51: 319–329.
ClobertJ. et al. 2009. Informed dispersal, heterogeneity in animal dispersal syndromes and the dynamics of spatially structured populations. – Ecol. Lett. 12: 197–209.
ClobertJ. et al. 2012. Dispersal ecology and evolution. – Oxford Univ. Press.
CosentinoB. J. et al. 2011. Connectivity of agroecosystems: dispersal costs can vary among crops. – Landscape Ecol.26: 371–379.
CoteJ. et al. 2013. Personality-dependent dispersal cancelled under predation risk. – Proc. R. Soc. B280: 20132349.
CoteJ. et al. 2017. Evolution of dispersal strategies and dispersal syndromes in fragmented landscapes. – Ecography40: 56–73.
CushmanS. A. 2006. Effects of habitat loss and fragmentation on amphibians: a review and prospectus. – Biol. Conserv.128: 231–240.
DalyJ. W. 1995. The chemistry of poisons in amphibian skin. – Proc. Natl Acad. Sci. USA92: 9–13.
DarlingtonR. B.SmuldersT. V. 2001. Problems with residual analysis. – Anim. Behav.3: 599–602.
EwertJ.-P.TraudR. 1979. Releasing stimuli for antipredator behaviour in the common toad Bufo bufo (L.). – Behaviour68: 170–180.
EycottA. E. et al. 2012. A meta-analysis on the impact of different matrix structures on species movement rates. – Landscape Ecol.27: 1263–1278.
FahrigL. 2003. Effects of habitat fragmentation on biodiversity. – Annu. Rev. Ecol. Evol. Syst.34: 487–515.
FahrigL. 2007. Non-optimal animal movement in human-altered landscapes. – Funct. Ecol.21: 1003–1015.
FlowersM. A.GravesB. M. 1997. Juvenile toads avoid chemical cues from snake predators. – Anim. Behav.53: 641–646.
García-BerthouE. 2001. On the misuse of residuals in ecology: testing regression residuals vs the analysis of covariance.– J. Anim. Ecol.70: 708–711.
GilliamJ. F.FraserD. F. 2001. Movement in corridors: enhancement by predation threat, disturbance and habitat structure. – Ecology82: 258–273.
GoaterC. P. et al. 1993. Effects of body size and parasite infection on the locomotory performance of juvenile toads, Bufo bufo. – Oikos66: 129–136.
GonzaloA. et al. 2008. Avoidance responses to scents of snakes that pose different risks of predation by adult natterjack toads, Bufo calamita. – Can. J. Zool.86: 928–932.
GriffithsR. A. et al. 1998. Behavioural responses of Mallorcan midwife toad tadpoles to natural and unnatural snake predators. – Anim. Behav.55: 207–214.
HoffmanJ.KatzU. 1989. The ecological significance of burrowing behaviour in the toad (Bufo viridis). – Oecologia81: 510–513.
JaninA. et al. 2009. Assessing landscape connectivity with calibrated cost-distance modelling: predicting common toad distribution in a context of spreading agriculture. – J. Appl. Ecol.46: 833–841.
JaninA. et al. 2011. Beyond occurrence: body condition and stress hormone as integrative indicators of habitat availability and fragmentation in the common toad. – Biol. Conserv.144: 1008–1016.
JaninA. et al. 2012. Use of stress-hormone levels and habitat selection to assess functional connectivity of a landscape for an amphibian. – Conserv. Biol.26: 923–931.
JaraF. G.PerottiM. G. 2009. Toad tadpole responses to predator risk: ontogenetic change between constitutive and inducible defenses. – J. Herpetol.43: 82–88.
JolyP. et al. 2003. Habitat fragmentation and amphibian conservation: building a tool for assessing landscape matrix connectivity. – CR. Biol.326: 132–139.
KieseckerJ. M. et al. 1996. The use of chemical cues in predator recognition by western toad tadpoles. – Anim. Behav.52: 1237–1245.
KnowltonJ. L.GrahamC. H. 2010. Using behavioral landscape ecology to predict species’ responses to land-use and climate change. – Biol. Conserv.143: 1342–1354.
LegrandD. et al. 2012. The Metatron: an experimental system to study dispersal and metaecosystems for terrestrial organisms. – Nat. Methods9: 828.
LegrandD. et al. 2015. Ranking the ecological causes of dispersal in a butterfly. – Ecography38: 822–831.
LegrandD. et al. 2016. Evolution of a butterfly dispersal syndrome. – Proc. R. Soc. B283: 20161533.
MazerolleM.DesrochersA. 2005. Landscape resistance to frog movements. – Can. J. Zool.83: 455–464.
MohammadiS. et al. 2016. Toxin-resistant isoforms of Na+/K+-ATPase in snakes do not closely track dietary specialization on toads. – Proc. R. Soc. B283: 20162111.
NakagawaS.CuthillI. C. 2007. Effect size, confidence interval and statistical significance: a practical guide for biologists. – Biol. Rev.82: 591–605.
OusterhoutB. H.SemlitschR. D. 2018. Effects of conditionally expressed phenotypes and environment on amphibian dispersal in nature. – Oikos127: 1142–1151.
PeacorS. D. 2002. Positive effect of predators on prey growth rate through induced modifications of prey behaviour. – Ecol. Lett.5: 77–85.
PennekampF. et al. 2014. Dispersal propensity in Tetrahymena thermophila ciliates – a reaction norm perspective. – Evolution68: 2319–2330.
PhillipsB. L. et al. 2006. Invasion and the evolution of speed in toads. – Nature439: 803.
PittmanS. E. et al. 2014. Movement ecology of amphibians: a missing component for understanding population declines. – Biol. Conserv.169: 44–53.
PopescuV. D.HunterM. L. 2011. Clear-cutting affects habitat connectivity for a forest amphibian by decreasing permeability to juvenile movements. – Ecol. Appl.21: 1283–1295.
PreestM. R.PoughF. H. 1989. Interaction of temperature and hydration on locomotion of toads. – Funct. Ecol.3: 693–699.
PrevedelloJ. A. et al. 2010. Movement behaviour within and beyond perceptual ranges in three small mammals: effects of matrix type and body mass. – J. Anim. Ecol.79: 1315–1323.
PukyM. 2005. Amphibian road kills: a global perspective. – Road Ecology Centre, Univ. of California, Davis. , accessed August 2018.
ReadingC. 1991. The relationship between body length, age and sexual maturity in the common toad, Bufo bufo. – Ecography14: 245–249.
ReadingC.DaviesJ. 1996. Predation by grass snakes (Natrix natrix) at a site in southern England. – J. Zool.239: 73–82.
ReimE. et al. 2018. Emigration propensity and flight performance are decoupled in a butterfly. – Ecosphere9: e02502.
RelyeaR. A. 2007. Getting out alive: how predators affect the decision to metamorphose. – Oecologia152: 389–400.
RittenhouseT. A. et al. 2008. The role of microhabitats in the desiccation and survival of anurans in recently harvested oak–hickory forest. – Copeia2008: 807–814.
RittenhouseT. A. et al. 2009. Survival costs associated with wood frog breeding migrations: effects of timber harvest and drought. – Ecology90: 1620–1630.
RohrJ. R.MadisonD. M. 2003. Dryness increases predation risk in efts: support for an amphibian decline hypothesis. – Oecologia135: 657–664.
RonceO.ClobertJ. 2012. Dispersal syndromes. – In: Clobert, J. et al. (eds), Dispersal ecology and evolution. Oxford Univ. Press, pp. 119–138.
RothermelB. B.LuhringT. M. 2005. Burrow availability and desiccation risk of mole salamanders (Ambystoma talpoideum) in harvested versus unharvested forest stands. – J. Herpetol.39: 619–626.
SantosX. et al. 2007. Evaluating factors affecting amphibian mortality on roads: the case of the common toad Bufo bufo, near a breeding place. – Anim. Biodivers. Conserv.30: 97–104.
ScribnerK. T. et al. 2001. Environmental correlates of toad abundance and population genetic diversity. – Biol. Conserv.98: 201–210.
SemlitschR. D. 2008. Differentiating migration and dispersal processes for pond-breeding amphibians. – J. Wildl. Manage.72: 260–267.
StevensV. M. et al. 2004. Quantifying functional connectivity: experimental evidence for patch-specific resistance in the natterjack toad (Bufo calamita). – Landscape Ecol.19: 829–842.
StevensV. M. et al. 2014. A comparative analysis of dispersal syndromes in terrestrial and semi-terrestrial animals. – Ecol. Lett.17: 1039–1052.
ToledoL. F. et al. 2011. Behavioural defences of anurans: an overview. – Ethol. Ecol. Evol.23: 1–25.
TrochetA. et al. 2013. Population sex ratio and dispersal in experimental, two-patch metapopulations of butterflies. – J. Anim. Ecol.82: 946–955.
TrochetA. et al. 2016. Intra-specific variability of hindlimb length in the palmate newt: an indicator of population isolation induced by habitat fragmentation?– Biol. Lett.12: 20160066.
TrochetA. et al. 2019. Influence of substrate types and morphological traits on movement behavior in a toad and newt species. – PeerJ6: e6053.
ÜvegesB. et al. 2017. Age- and environment-dependent changes in chemical defences of larval and post-metamorphic toads. – BMC Evol. Biol.17: 137.
Van BocxlaerI. et al. 2010. Gradual adaptation toward a range-expansion phenotype initiated the global radiation of toads. – Science327: 679–682.
WatlingJ. I.BragaL. 2015. Desiccation resistance explains amphibian distributions in a fragmented tropical forest landscape. – Landscape Ecol.30: 1449–1459.
WinandyL. et al. 2019. Data from: local predation risk and matrix permeability interact to shape movement strategy. – Dryad Digital Repository, .
ZuurA. F. et al. 2009. Mixed effects models and extensions in ecology with R. – Spring Science and Business Media.
