Search results for "EDUCATED PREDATORS"

showing 4 items of 4 documents

Predators' consumption of unpalatable prey does not vary as a function of bitter taste perception

2020

Many prey species contain defensive chemicals that are described as tasting bitter. Bitter taste perception is, therefore, assumed to be important when predators are learning about prey defenses. However, it is not known how individuals differ in their response to bitter taste, and how this influences their foraging decisions. We conducted taste perception assays in which wild-caught great tits (Parus major) were given water with increasing concentrations of bitter-tasting chloroquine diphosphate until they showed an aversive response to bitter taste. This response threshold was found to vary considerably among individuals, ranging from chloroquine concentrations of 0.01 mmol/L to 8 mmol/L.…

0106 biological sciencesEXPRESSIONDEFENSEmedia_common.quotation_subjectbitter tasteLibrary scienceConsumption (sociology)BiologySTRATEGIC DECISIONS010603 evolutionary biology01 natural sciencesBasic Behavioral and Social ScienceMONARCH BUTTERFLIES03 medical and health sciencesREPERTOIREBitter taste perceptionchemical defenseAvoidance learningExcellenceFOODBehavioral and Social ScienceaposematismDental/Oral and Craniofacial DiseaseEcology Evolution Behavior and SystematicsEDUCATED PREDATORS030304 developmental biologyIndependent researchmedia_commonNutrition0303 health sciencesBIRDSFOS: Clinical medicine3103 EcologyNeurosciencestoxinsBitter tastehumanitiesEVOLUTIONgreat titsRECEPTORS3109 ZoologyResearch councilavoidance learning1181 Ecology evolutionary biologybehavior and behavior mechanismsAnimal Science and Zoology31 Biological Sciences
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Social information use about novel aposematic prey is not influenced by a predator’s previous experience with toxins

2019

Aposematism is an effective antipredator strategy. However, the initial evolution and maintenance of aposematism are paradoxical because conspicuous prey are vulnerable to attack by naive predators. Consequently, the evolution of aposematic signal mimicry is also difficult to explain. The cost of conspicuousness can be reduced if predators learn about novel aposematic prey by observing another predator's response to that same prey. On the other hand, observing positive foraging events might also inform predators about the presence of undefended mimics, accelerating predation on both mimics and their defended models. It is currently unknown, however, how personal and social information combi…

0106 biological sciencespredator-prey interactionstoksiinitZoologyAVOIDANCEAposematismBiology41 Environmental SciencesSTRATEGIC DECISIONSALTERNATIVE PREYFREQUENCY010603 evolutionary biology01 natural sciencesBATESIAN MIMICRYBasic Behavioral and Social SciencePredation03 medical and health sciencesDEFENDED PREYpetoeläimetBehavioral and Social ScienceCOLOR BIASEStoxin loadaposematismAVERSIONSSocial informationPredatorEcology Evolution Behavior and SystematicsEDUCATED PREDATORS030304 developmental biologysuojaväri0303 health sciencessaaliseläimetmimikry3103 EcologySocial learningBLACKBIRDSBatesian mimicrysosiaalinen oppiminengreat titssocial learning3109 Zoology1181 Ecology evolutionary biologyMimicrymimicry31 Biological Sciences
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Multimodal Aposematic Defenses Through the Predation Sequence

2021

Aposematic organisms warn predators of their unprofitability using a combination of defenses, including visual warning signals, startling sounds, noxious odors, or aversive tastes. Using multiple lines of defense can help prey avoid predators by stimulating multiple senses and/or by acting at different stages of predation. We tested the efficacy of three lines of defense (color, smell, taste) during the predation sequence of aposematic wood tiger moths (Arctia plantaginis) using blue tit (Cyanistes caeruleus) predators. Moths with two hindwing phenotypes (genotypes: WW/Wy = white, yy = yellow) were manipulated to have defense fluid with aversive smell (methoxypyrazines), body tissues with a…

varoitusväri0106 biological sciencesTastepredator-prey interactionsPyrrolizidine alkaloidEvolutiondefense mechanismsmultimodal signalingPREYAVOIDANCEZoologyContext (language use)AposematismITHOMIINE BUTTERFLIESBiology010603 evolutionary biology01 natural sciencestäpläsiilikäsPredation03 medical and health scienceschemistry.chemical_compoundCyanistes caeruleuschemical defensePYRROLIZIDINE ALKALOIDSQH359-425aposematismpuolustusmekanismit (biologia)Arctia plantaginissinitiainenQH540-549.5EDUCATED PREDATORSEcology Evolution Behavior and Systematics030304 developmental biology0303 health sciencesTASTEEcologyfungiCyanistesbiology.organism_classificationsaalistusWARNING COLORATIONCHEMICAL DEFENSEchemistryTRADE-OFFwarning signals1181 Ecology evolutionary biologyPyrrolizidineChemical defensePYRAZINE ODORFrontiers in Ecology and Evolution
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Seeing red? Colour biases of foraging birds are context dependent.

2020

Funder: Suomen Kulttuurirahasto; doi: http://dx.doi.org/10.13039/501100003125

warning colouration0106 biological sciencesgenetic structuresFood choicefood choicePREFERENCESTrade-off01 natural sciencesPredationFood choiceDOMESTIC CHICKSAvoidance learningPasseriformessinitiainenEDUCATED PREDATORSbiology05 social sciencesCyanistestalitiainenREDWINGS TURDUS-ILIACUSWarning colourationcolour preferenceBiological Evolutiongreat titsTRADE-OFFavoidance learning1181 Ecology evolutionary biologyEAT DEFENDED PREYvaroitusväriFRUIT COLORGreat titsForagingZoologyColorExperimental and Cognitive PsychologyColour preferenceeläinten käyttäytyminen010603 evolutionary biologyväritBlue titsBiasFOODJuvenileAnimals0501 psychology and cognitive sciences050102 behavioral science & comparative psychologySensory cueEcology Evolution Behavior and SystematicsParusblue titsOriginal Paperbiology.organism_classificationsaalistusPATTERNFruitAPOSEMATIC INSECT
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