Temporal habitat shift of a polymorphic newt species under predation risk

Winandy, Laurane; Colin, Mélanie; Denoël, Mathieu

doi:10.1093/beheco/arw008

Download

Article (Scientific journals)

Temporal habitat shift of a polymorphic newt species under predation risk

Winandy, Laurane; Colin, Mélanie; Denoël, Mathieu

2016 • In Behavioral Ecology, 27 (4), p. 1025-1032

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/193100

DOI
10.1093/beheco/arw008

Files (2)Send to Details Statistics Bibliography Similar publications

Files

Full Text

Behav_Ecol_2016_Author-Version.pdf

Author postprint (1.2 MB)

This is the Author version of the published manuscript available in open access

Download

Full Text Parts

Behav_Ecol_2016.pdf

Publisher postprint (5.4 MB)

This is the pdf of the published paper

Request a copy

This paper is published by Oxford University Press on behalf of the International Society for Behavioral Ecology

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Keywords :

alien species; amphibians; antipredator behavior; behavioral avoidance; risk allocation hypothesis; diel pattern; risk assesment; palmate newt; paedomorphosis; shelter use; night; resource partitioning; larzac; infra-red; temporal partitioning; goldfish; Carassius auratus; habitat; day activity; night activity; nocturnal activity

Abstract :

[en] The temporal partitioning hypothesis suggests that the evolution of different diel activity rhythms in animals might facilitate the coexistence between prey and predators. However, the temporal shift of habitat use induced by predation has rarely been observed. The study of such a mechanism is particularly relevant for introduced species because it might explain how native species can persist or decline in response to the presence of alien species. The introduction of fish into ponds inhabited by amphibians has severe consequences for their occurrence and abundance. Fish particularly affect an alternative newt phenotype, the paedomorph, which does not undergo metamorphosis and maintains larval traits such as gills at the adult stage. In a laboratory design, we assessed the diel patterns of habitat use in the 2 distinct morphological phenotypes of palmate newt (Lissotriton helveticus) in the presence or absence of goldfish (Carassius auratus). Both newt phenotypes avoided a risky habitat more in the presence than in the absence of fish. This habitat shift was more pronounced during the daytime (i.e., when the risk could be considered higher for the newts) than during nighttime. However, in contrast to metamorphs, paedomorphs showed less adaptive changes according to temporal risk and remained in their shelter for most of the time. Temporal and habitat partitioning at the diel scale between native and alien species might promote their coexistence, but diel change can also imply a cost in the overall reduction of the time allocated to essential activities, showing that species interactions remain complex.

Research center :

AFFISH-RC - Applied and Fundamental FISH Research Center - ULiège

Disciplines :

Animal psychology, ethology & psychobiology
Aquatic sciences & oceanology
Environmental sciences & ecology

Author, co-author :

Winandy, Laurane ; Université de Liège > Département de Biologie, Ecologie et Evolution > Biologie du comportement - Ethologie et psychologie animale

Colin, Mélanie; Univrersité de Liège > Unité de Biologie du Comportement

Denoël, Mathieu ; Université de Liège > Département de Biologie, Ecologie et Evolution > Biologie du comportement - Ethologie et psychologie animale

Language :

English

Title :

Temporal habitat shift of a polymorphic newt species under predation risk

Publication date :

July 2016

Journal title :

Behavioral Ecology

ISSN :

1045-2249

eISSN :

1465-7279

Publisher :

Oxford University Press - Journals Department, Oxford, United Kingdom

Volume :

Issue :

Pages :

1025-1032

Peer reviewed :

Peer Reviewed verified by ORBi

Funders :

F.R.S.-FNRS - Fonds de la Recherche Scientifique [BE]
ULg FSR - Université de Liège. Fonds spéciaux pour la recherche [BE]

Available on ORBi :

since 10 February 2016

Statistics

Number of views

184 (37 by ULiège)

Number of downloads

101 (11 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

Bibliography

Andreone F, Dore B, Usai P, Paraninfo A. 1993. Skin morphology in larval, paedomorphic and metamorphosed Alpine newts, Triturus alpestris apuanus. Alytes. 11:25-35
Barr GE, Babbitt KJ. 2007. Trout affect the density, activity and feeding of a larval plethodontid salamander. Freshw Biol. 52:1239-1248
Bosiger YJ, Lonnstedt OM, McCormick MI, Ferrari MC. 2012. Learning temporal patterns of risk in a predator-diverse environment. PLoS One. 7:e34535
Bridges CM. 2002. Tadpoles balance foraging and predator avoidance: effects of predation, pond drying, and hunger. J Herpetol. 36:627-634
Burnham KP, Anderson DR. 2002. Model selection and multimodel inference a practical information-theoretic approach. New York: Springer Verlag
Demars B. 2004. Regime alimentaire des tritons palmes (Triturus helveticus) et alpestres (Triturus alpestris) dans des ornieres forestieres (Fagne, Belgique): variation temporelle et spatiale du partage des ressources trophiques [MSc thesis]. [Liege (Belgium)]: University of Liege
Denoel M. 2005a. Habitat partitioning in facultatively paedomorphic populations of palmate newts Triturus helveticus. Ambio. 34:476-477
Denoel M. 2005b. Persistance et dispersion d'une population introduite de triton alpestre (Triturus alpestris) dans les causses du Larzac (sud de la France). Rev Ecol. 60:139-148
Denoel M, Andreone F. 2003. Trophic habits and aquatic microhabitat use in gilled immature, paedomorphic and metamorphic Alpine newts (Triturus alpestris apuanus) in a pond in central Italy. Belg J Zool. 133:95-102
Denoel M, Doellen G. 2010. Displaying in the dark: light-dependent alternative mating tactics in the Alpine newt. Behav Ecol Sociobiol. 64:1171-1177
Denoel M, Džukić G, Kalezić ML. 2005. Effect of widespread fish introductions on paedomorphic newts in Europe. Conserv Biol. 19:162-170
Denoel M, Ficetola GF. 2014. Heterochrony in a complex world: disentangling environmental processes of facultative paedomorphosis in an amphibian. J Anim Ecol. 83:606-615
Denoel M, Ivanović A, Dzukić G, Kalezić ML. 2009. Sexual size dimorphism in the evolutionary context of facultative paedomorphosis: insights from European newts. BMC Evol Biol. 9:278
Denoel M, Joly P, Whiteman HH. 2005. Evolutionary ecology of facultative paedomorphosis in newts and salamanders. Biol Rev Camb Philos Soc. 80:663-671
Denoel M, Perez A, Cornet Y, Ficetola GF. 2013. Similar local and landscape processes affect both a common and a rare newt species. PLoS One. 8:e62727
Denoel M, Schabetsberger R, Joly P. 2004. Trophic specialisations in alternative heterochronic morphs. Naturwissenschaften. 91:81-84
Dolmen D. 1983a. Diel rhythms and microhabitat preference of the newts Triturus vulgaris and T. cristatus at the northern border of their distribution area. J Herpetol. 17:23-31
Dolmen D. 1983b. Diel rhythms of Triturus vulgaris (L.) and T. cristatus (Laurenti) (Amphibia) in central Norway. Gunneria. 42:1-34
Douglas PL, Forrester GE, Cooper SD. 1994. Effects of trout on the diel periodicity of drifting in baetid mayflies. Oecologia. 98:48-56
Esslinger GG, Bodkin JL, Breton AR, Burns JM, Monson DH. 2014. Temporal patterns in the foraging behavior of sea otters in Alaska. J Wildl Manage. 78:689-700
Ferrari MCO, Chivers DP. 2009. Temporal variability, threat sensitivity and conflicting information about the nature of risk: understanding the dynamics of tadpole antipredator behaviour. Anim Behav. 78:11-16
Ferrari MCO, Crane AL, Brown GE, Chivers DP. 2015. Getting ready for invasions: can background level of risk predict the ability of naive prey to survive novel predators? Sci Rep. 5:8309
Ferrari MCO, Elvidge CK, Jackson CD, Chivers DP, Brown GE. 2010. The responses of prey fish to temporal variation in predation risk: sensory habituation or risk assessment? Anim Behav. 35:420-425
Ferrari MCO, Messier F, Chivers DP. 2008. Larval amphibians learn to match antipredator response intensity to temporal patterns of risk. Behav Ecol. 19:980-983
Ferrari MCO, Sih A, Chivers DP. 2009. The paradox of risk allocation a review and prospectus. Anim Behav. 78:579-585
Gabrion J, Sentein P, Gabrion C. 1977. Les populations neoteniques de Triturus helveticus Raz. des Causses et du Bas-Languedoc. I. Repartition et caracteristiques. Terre Vie. 31:489-506
Gherardi F. 2007. Biological invaders in inland waters: profiles, distribution, and threats. Dordrecht (The Netherlands): Springer
Griffiths RA. 1985. Diel profile of behaviour in the smooth newt, Triturus vulgaris (L.) an analysis of environmental cues and endogenous timing. Anim Behav. 33:573-582
Grueber CE, Nakagawa S, Laws RJ, Jamieson IG. 2011. Multimodel inference in ecology and evolution: challenges and solutions. J Evol Biol. 24:699-711
Grusser-Cornehls U, Himstedt W. 1976. The urodele visual system. In: Fite KV, editor. The amphibian visual system. New York: Academic Press. p. 203-266
Hartel T, Nemes S, CogǍlniceanu D, Ollerer K, Schweiger O, Moga CI, Demeter L. 2007. The effect of fish and aquatic habitat complexity on amphibians. Hydrobiologia. 583:173-182
Hartman R, Lawler S. 2014. Evidence for contemporary evolution of behavioural responses to introduced fish. Anim Behav. 97:213-220
Hendry AP, Farrugia TJ, Kinnison MT. 2008. Human influences on rates of phenotypic change in wild animal populations. Mol Ecol. 17:20-29
Himstedt W. 1967. Experimentelle analyse der optischen sinnesleistungen im beutefangverhalten der einheimischen urodelen. Zool Jb Physiol. 73:281-320
Himstedt W. 1971. Die tagesperiodik von Salamandriden. Oecologia. 8:194-208
Himstedt W. 1973. Die spektrale empfindlichkeit von urodelen in abhangigkeit von metamorphose, jahreszeit und lebensraum. Zool Jb Physiol. 77:246-274
Holomuzki JR. 1986. Predator avoidance and diel patterns of microhabitat use by larval tiger salamanders. Ecology. 67:737-748
Iigo M, Tabata M. 1996. Circadian rhythms of locomotor activity in the goldfish Carassius auratus. Physiol Behav. 60:775-781
Jacobsen L, Berg S. 1998. Diel variation in habitat use by planktivores in field enclosure experiments: the effect of submerged macrophytes and predation. J Fish Biol. 53:1207-1219
Kesler DH, Munns WR Jr. 1991. Diel feeding by adult red-spotted newts in the presence and absence of sunfish. J Freshw Ecol. 6:267-273
Kronfeld-Schor N, Dayan T. 2003. Partitioning of time as an ecological resource. Annu Rev Ecol Evol Syst. 34:153-181
Landi M, Piazzini S, Saveri C. 2014. The response of amphibian communities to fish and habitat features in Mediterranean permanent ponds. Biologia. 69:806-810
Lima SL. 1998a. Stress and decision making under the risk of predation: recent developments from behavioral, reproductive, and ecological perspectives. Adv Study Behav. 27:215-290
Lima SL. 1998b. Nonlethal effects in the ecology of predator-prey interactions: what are the ecological effects of anti-predator decision-making? Bioscience. 48:25-35
Lima SL, Bednekoff PA. 1999. Temporal variation in danger drives antipredator behavior: the predation risk allocation hypothesis. Am Nat. 153:649-659
Lima SL, Dill LM. 1990. Behavioral decisions made under the risk of predation a review and prospectus. Can J Zool. 68:619-640
Lopez-Olmeda JF, Madrid JA, Sanchez-Vazquez FJ. 2006. Melatonin effects on food intake and activity rhythms in two fish species with different activity patterns: diurnal (goldfish) and nocturnal (tench). Comp Biochem Physiol A Mol Integr Physiol. 144:180-187
Maceda-Veiga A, Escribano-Alacid J, de Sostoa A, Garcia-Berthou E. 2013. The aquarium trade as a potential source of fish introductions in southwestern Europe. Biol Invasions. 15:2707-2716
Madison DM, Maerz JC, McDarby JH. 1999. Optimization of predator avoidance by salamanders using chemical cues: diet and diel effects. Ethology. 105:1073-1086
Manenti R, Denoel M, Ficetola GF. 2013. Foraging plasticity favours adaptation to new habitats in fire salamanders. Anim Behav. 86:375-382
Martin E. 1982. Distribution des activites comportementales chez le Triton alpestre Triturus alpestris (Amphibien, Urodele) en phase aquatique: etude de la variabilite interindividuelle et de l'intensification locale [dissertation]. [Lyon (France)]: Universite de Claude Bernard Lyon 1
Martin B, Bateson P. 2007. Measuring behavior an introductory guide. Cambridge (UK): Cambridge University Press
Martin E, Joly P, Bovet P. 1989. Diel pattern of activity in the alpine newt (Triturus alpestris, Amphibia Uredola) during the aquatic phase. Biol Behav. 14:116-131
Mazerolle MJ. 2006. Improving data analysis in herpetology: using Akaike's Information Criterion (AIC) to assess the strength of biological hypotheses. Amphib Reptil. 27:169-180
McGeoch MA, Butchart SHM, Spear D, Marais E, Kleynhans EJ, Symes A, Chanson J, Hoffmann M. 2010. Global indicators of biological invasion: species numbers, biodiversity impact and policy responses. Divers Distrib. 16:95-108
Metcalfe NB, Fraser NHC, Burns MD. 1999. Food availability and the nocturnal vs. diurnal foraging trade-off in juvenile salmon. J Anim Ecol. 68:371-381
Miaud C. 1993. Predation of newt eggs (Triturus alpestris and T. helveticus): identification of predators and protective role of oviposition behavior. J Zool. 231:575-582
Miaud C. 1995. Oviposition site selection in three species of European newts (Salamandridae) genus Triturus. Amphib Reptil. 16:265-272
Monello RJ, Wright RG. 2001. Predation by goldfish (Carassius auratus) on eggs and larvae of the eastern long-toed salamander (Ambystoma macrodactylum columbianum). J Herpetol. 35:350-353
Neumeyer C. 1986. Wavelength discrimination in the goldfish. J Comp Physiol A. 158:203-213
Neumeyer C, Wietsma JJ, Spekreijse H. 1991. Separate processing of "color" and "brightness" in goldfish. Vision Res. 31:537-549
Nunn AD, Tewson LH, Cowx IG. 2012. The foraging ecology of larval and juvenile fishes. Rev Fish Biol Fisher. 22:377-408
Oberrisser P, Waringer J. 2011. Larval salamanders and diel drift patterns of aquatic invertebrates in an Austrian stream. Freshw Biol. 56:1147-1159
Pinheiro P, Bates D. 2000. Mixed-effect models in S and S-Plus. New York: Springer
Poudel BS, Spooner PG, Matthews A. 2015. Temporal shift in activity patterns of Himalayan marmots in relation to pastoralism. Behav Ecol. 26:1345-1351
Richardson MJ, Whoriskey FG, Roy LH. 1995. Turbidity generation and biological impacts of an exotic fish Carassius auratus, introduced into shallow seasonality anoxic ponds. J Fish Biol. 47:576-585
Ross J, Hearn AJ, Johnson PJ, Macdonald DW. 2013. Activity patterns and temporal avoidance by prey in response to Sunda clouded leopard predation risk. J Zool. 290:96-106
Salo P, Korpimaki E, Banks PB, Nordstrom M, Dickman CR. 2007. Alien predators are more dangerous than native predators to prey populations. Proc Biol Sci B. 274:1237-1243
Sanchez-Vazquez FJ, Madrid JA, Zamora S, Tabata M. 1997. Feeding entrainment of locomotor activity rhythms in the goldfish is mediated by a feeding-entrainable circadian oscillator. J Comp Physiol A Sens Neural Behav Physiol. 181:121-132
Savini D, Occhipinti-Ambrogi A, Marchini A, Tricarico E, Gherardi F, Olenin S, Gollasch S. 2010. The top 27 animal alien species introduced into Europe for aquaculture and related activities. J Appl Ichthyol. 26:1-7
Schoener TW. 1974. Resource partitioning in ecological communities. Science. 185:27-39
Seliskar A, Pehani H. 1935. Limnologische Beitrage zum Problem der Amphibienneotenie (Beobachtungen an Tritonen der Triblavseen). Verh Internat Verein Theor Angew Limnol. 7:263-294
Sih A, Ferrari MC, Harris DJ. 2011. Evolution and behavioural responses to human-induced rapid environmental change. Evol Appl. 4:367-387
Sih A, Ziemba R, Harding HC. 2000. New insights on how temporal variation in predation risk shapes prey behavior. Trends Ecol Evol. 15:3-4
Skelly DK. 1994. Activity level and the susceptibility of anuran larvae to predation. Anim Behav. 47:465-468
Sonnichsen L, Bokje M, Marchal J, Hofer H, Jedrzejewska B, Kramer-Schadt S, Ortmann S. 2013. Behavioural responses of European roe deer to temporal variation in predation risk. Ethology. 119:233-243
Stuart SN, Chanson JS, Cox NA, Young BE, Rodrigues AS, Fischman DL, Waller RW. 2004. Status and trends of amphibian declines and extinctions worldwide. Science. 306:1783-1786
Stuart-Smith RD, White RWG, Barmuta LA. 2008. A shift in the habitat use pattern of a lentic galaxiid fish an acute behavioural response to an introduced predator. Environ Biol Fish. 82:93-100
Tavolga WN. 1977. Behavioural thresholds for diffuse illumination in the goldfish. J Exp Biol. 67:89-96
Treer D. 2015. Integrative studies on sex pheromones in European newts [dissertation]. [Brussel (Belgium)]: Vrije Universiteit Brussel
Verrell PA. 1984. Responses to different densities of males in the smooth newt, Triturus vulgaris. "One at a time, please". J Herpetol. 18:482-484
Voss SR, Kump DK, Walker JA, Shaffer HB, Voss GJ. 2012. Thyroid hormone responsive QTL and the evolution of paedomorphic salamanders. Heredity (Edinb). 109:293-298
Wake DB, Vredenburg VT. 2008. Are we in the midst of the sixth mass extinction? A view from the world of amphibians. Proc Natl Acad Sci USA. 105:11466-11473
Wambreuse P, Bels V. 1984. Analyse qualitative et quantitative de la parade sexuelle du triton palme Triturus helveticus (Razoumowsky 1798). Cah Ethol Appl. 4:193-218
Wimpenny RS. 1951. The effect of vegetation on the breeding of newts, Molge cristata and Molge vulgaris. J Anim Ecol. 20:98-102
Winandy L, Darnet E, Denoel M. 2015. Amphibians forgo aquatic life in response to alien fish introduction. Anim Behav. 109:209-216
Winandy L, Denoel M. 2013a. Introduced goldfish affect amphibians through inhibition of sexual behaviour in risky habitats an experimental approach. PLoS One. 8:e82736
Winandy L, Denoel M. 2013b. Cues from introduced fish alter shelter use and feeding behaviour in adult alpine newts. Ethology. 119:121-129
Winandy L, Denoel M. 2015a. The aggressive personality of an introduced fish affects foraging behavior in a polymorphic newt. Behav Ecol. 26:1528-1536
Winandy L, Denoel M. 2015b. Expression of sexual ornaments in a polymorphic species: phenotypic variation in response to environmental risk. J Evol Biol. 28:1049-1056