Search results for "crypsis"

showing 10 items of 21 documents

Throwing down a genomic gauntlet on fisheries-induced evolution

2021

Beginning with studies on crypsis and camouflage, the hypothesis that predators can generate evolutionary change in their prey has a long and rich history (1). Few predators, however, rival humans in their potential to generate selection responses and concomitant phenotypic change on contemporary timescales. In the 1930s, J. B. S. Haldane (2) mused that fishing would be an ideal candidate for such “observable evolution” within a human lifetime, proceeding “with extreme and abnormal speed.” However, it was not until the late 1970s that research on fisheries-induced evolution (FIE) gained a substantive scientific foothold, beginning with thought-provoking work on Canadian whitefish ( Coregonu…

0106 biological sciences0301 basic medicineCoregonus clupeaformisFishingFisheriesevoluutioBiodiversity437430Polymorphism Single Nucleotide010603 evolutionary biology01 natural sciencesPredation03 medical and health sciencesPer capitaAnimals14. Life underwaterSemelparity and iteroparityPopulation DensityMultidisciplinaryPopulation BiologybiologykalakannatFishesGenomicsgenomiikkaBiological Sciencesbiology.organism_classificationBiological EvolutionkalastusFisherykalatalousOverexploitation030104 developmental biologyCrypsisCommentaryProceedings of the National Academy of Sciences
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Repeated evolution of camouflage in speciose desert rodents

2017

AbstractThere are two main factors explaining variation among species and the evolution of characters along phylogeny: adaptive change, including phenotypic and genetic responses to selective pressures, and phylogenetic inertia, or the resemblance between species due to shared phylogenetic history. Phenotype-habitat colour match, a classic Darwinian example of the evolution of camouflage (crypsis), offers the opportunity to test the importance of historical versus ecological mechanisms in shaping phenotypes among phylogenetically closely related taxa. To assess it, we investigated fur (phenotypic data) and habitat (remote sensing data) colourations, along with phylogenetic information, in t…

0106 biological sciences0301 basic medicineGenotypeScienceevoluutioZoologyColorBiology010603 evolutionary biology01 natural sciencesArticle03 medical and health sciencesPhylogeneticscamouflageAnimalsAnimal FurEcosystemPhylogenyPhylogenetic inertiaMultidisciplinaryPhylogenetic treeBiological MimicryQRspeciose desert rodents15. Life on landbiology.organism_classificationGerbillusBiological Evolution030104 developmental biologyTaxonPhenotypeHabitatCamouflageCrypsisMedicineGerbillinae
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Social transmission of avoidance among predators facilitates the spread of novel prey.

2018

Warning signals are an effective defence strategy for aposematic prey, but only if they are recognized by potential predators. If predators must eat prey to associate novel warning signals with unpalatability, how can aposematic prey ever evolve? Using experiments with great tits (Parus major) as predators, we show that social transmission enhances the acquisition of avoidance by a predator population. Observing another predator’s disgust towards tasting one novel conspicuous prey item led to fewer aposematic than cryptic prey being eaten for the predator population to learn. Despite reduced personal encounters with unpalatable prey, avoidance persisted and increased over subsequent trials.…

0106 biological sciences0301 basic medicineMaleINFORMATION01 natural sciencesPredationSongbirdsFood chainTITS PARUS-MAJORPredatorDISTASTEFUL PREYeducation.field_of_studyEcologyEcologytalitiainenCrypsis1181 Ecology evolutionary biologySURVIVAL590 Animals (Zoology)FemaleAPOSEMATIC PREYWARNING SIGNALSvaroitusväriCONSPICUOUS PREYFood ChainPopulationAposematismBiology010603 evolutionary biologyeläinten käyttäytyminenModels Biological03 medical and health sciences10127 Institute of Evolutionary Biology and Environmental StudiesAvoidance LearningAnimalseducationSocial BehaviorEcology Evolution Behavior and SystematicsParusbiology.organism_classificationDisgustEVOLUTIONsaalistus030104 developmental biology1105 Ecology Evolution Behavior and Systematicssocial transmissionDIETARY CONSERVATISMPredatory Behavior570 Life sciences; biologyGREAT TITS2303 Ecology
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Transparency reduces predator detection in chemically protected clearwing butterflies

2018

Abstract1. Predation is an important selective pressure and some prey have evolved warning colour signals advertising unpalatability (i.e. aposematism) as an antipredator strategy. Unexpectedly, some butterfly species from the unpalatable tribe Ithomiini possess transparent wings, an adaptation rare on land but common in water where it helps avoiding predator detection.2. We tested if transparency of butterfly wings was associated with decreased detectability by predators, by comparing four butterfly species exhibiting different degrees of transparency, ranging from fully opaque to largely transparent. We tested our prediction using using both wild birds and humans in behavioural experiment…

0106 biological sciences0303 health sciencesbiologyTransparency (market)ZoologyAposematismbiology.organism_classification010603 evolutionary biology01 natural sciencesIthomiiniPredation03 medical and health sciencesButterflyCrypsisAdaptationPredator030304 developmental biology
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Warning coloration can be disruptive: aposematic marginal wing patterning in the wood tiger moth

2015

Warning (aposematic) and cryptic colorations appear to be mutually incompatible because the primary function of the former is to increase detectability, whereas the function of the latter is to decrease it. Disruptive coloration is a type of crypsis in which the color pattern breaks up the outline of the prey, thus hindering its detection. This delusion can work even when the prey’s pattern elements are highly contrasting; thus, it is possible for an animal’s coloration to combine both warning and disruptive functions. The coloration of the wood tiger moth (Parasemia plantaginis) is such that the moth is conspicuous when it rests on vegetation, but when it feigns death and drops to the gras…

0106 biological sciencesAposematismdisruptive coloration010603 evolutionary biology01 natural sciencesPredation03 medical and health sciencesDisruptive colorationParasemia plantaginiscamouflageaposematismEcology Evolution Behavior and SystematicsOriginal Research030304 developmental biologyNature and Landscape ConservationParusdistruptive coloration0303 health sciencesWingEcologybiologyEcologybiology.organism_classificationsaalistuscrypsisdefenseCamouflageCrypsista1181predationEcology and Evolution
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Specific color sensitivities of prey and predator explain camouflage in different visual systems

2004

In situations of aggressive mimicry, predators adapt their color to that of the substrate on which they sit for hunting, a behavior that is presumed to hide them from prey as well as from their own predators. Females of few crab-spider species encounter such situations when lying on flowers to ambush pollinators. To evaluate the efficiency of spider camouflage on flowers, we measured by spectroradiometry adult female Thomisus onustus and marguerite daisies, Leucanthemum vulgare. We compared chromatic contrast (color used for short-range detection) of each pair of spider and flower to detection thresholds computed in the visual systems of both Hymenopteran prey and passerine bird predator. W…

0106 biological sciences[SDV.OT]Life Sciences [q-bio]/Other [q-bio.OT]0303 health sciencesSpiderbiology[SDV.OT] Life Sciences [q-bio]/Other [q-bio.OT]Ecologybiology.organism_classification010603 evolutionary biology01 natural sciencesPasserinePredation03 medical and health sciencesCamouflagebiology.animalThomisus onustusCrypsisAggressive mimicryAnimal Science and Zoology[ SDV.OT ] Life Sciences [q-bio]/Other [q-bio.OT]bird; camouflage; crab-spider; Hymenoptera; spectrometryPredatorComputingMilieux_MISCELLANEOUSEcology Evolution Behavior and Systematics030304 developmental biologyBehavioral Ecology
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Unexpected diversity in socially synchronized rhythms of shorebirds.

2016

The behavioural rhythms of organisms are thought to be under strong selection, influenced by the rhythmicity of the environment1,2,3,4. Such behavioural rhythms are well studied in isolated individuals under laboratory conditions1,5, but free-living individuals have to temporally synchronize their activities with those of others, including potential mates, competitors, prey and predators6,7,8,9,10. Individuals can temporally segregate their daily activities (for example, prey avoiding predators, subordinates avoiding dominants) or synchronize their activities (for example, group foraging, communal defence, pairs reproducing or caring for offspring)6,7,8,9,11. The behavioural rhythms that em…

0301 basic medicineMale0106 biological sciencesPeriodicityTime FactorsZygoteBehavioural ecologyCaptivityBiológiai tudományokEvolutionary ecology01 natural sciencesSEXUAL SELECTIONNesting BehaviorPredationCharadriiformesTermészettudományokNestPHYLOGENIESIncubationSocial evolution0303 health sciencesMultidisciplinaryROLESEcologyReproductionAnimal behaviourBiological EvolutionCircadian RhythmINCUBATION PATTERNSSexual selectionGEOLOCATOR DATACrypsisFemaleCIRCADIAN-RHYTHMSCuesPhotoperiodForagingNEST PREDATIONZoologyshorebirdsContext (language use)[SDV.BID]Life Sciences [q-bio]/BiodiversityEnvironmentBiology010603 evolutionary biologyCLOCKS03 medical and health sciencesRhythmSpecies SpecificityAnimals14. Life underwaterSensory cue030304 developmental biology[ SDV.BID ] Life Sciences [q-bio]/Biodiversity[ SDE.BE ] Environmental Sciences/Biodiversity and EcologyBIRDSFeeding BehaviorEVOLUTION030104 developmental biologyStarvationPredatory Behaviorsocially synchronized rhythmsta1181Evolutionary ecology[SDE.BE]Environmental Sciences/Biodiversity and Ecology
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Does predation maintain eyespot plasticity in Bicyclus anynana?

2004

The butterfly Bicyclus anynana exhibits phenotypic plasticity involving the wet-season phenotype, which possesses marginal eyespots on the ventral surface of the wings, and the dry-season form, which lacks these eyespots. We examined the adaptive value of phenotypic plasticity of B. anynana in relation to the defence mechanisms of crypsis and deflection. We assessed the visibility differences between spotless and spotted butterflies against backgrounds of brown (dry season) or green (wet season) leaves. Spotless butterflies were highly cryptic and less predated by adult bird predators than were spotted ones when presented against brown leaf litter. However, the advantage of crypsis disappea…

Adaptive valueClimateGeneral Biochemistry Genetics and Molecular BiologyPredationBirdsAnimalsWings AnimalSelection GeneticEcosystemGeneral Environmental SciencePhenotypic plasticityGeneral Immunology and MicrobiologybiologyEcologyPigmentationGeneral MedicineBicyclus anynanabiology.organism_classificationAdaptation PhysiologicalPhenotypePredatory BehaviorButterflyCrypsisEyespotBicyclusSeasonsGeneral Agricultural and Biological SciencesButterfliesResearch Article
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Seasonal changes in predator community switch the direction of selection for prey defences

2014

Insect communities consist of aposematic species with efficient warning colours against predation, as well as abundant examples of crypsis. To understand such coexistence, we here report results from a field experiment where relative survival of artificial larvae, varying in conspicuousness, was estimated in natural bird communities over an entire season. This takes advantage of natural variation in the proportion of naive predators: naivety peaks when young birds have just fledged. We show that the relative benefit of warning signals and crypsis changes accordingly. When naive birds are rare (early and late in the season), conspicuous warning signals improve survival, but conspicuousness b…

Food ChainNaivetymedia_common.quotation_subjectAdaptation BiologicalGeneral Physics and Astronomy1600 General ChemistryGenetics and Molecular BiologyInsectAposematismBiologyArticleStatistics NonparametricGeneral Biochemistry Genetics and Molecular BiologyPredationBirds10127 Institute of Evolutionary Biology and Environmental StudiesFood chainSpecies Specificity1300 General Biochemistry Genetics and Molecular BiologyAnimalsOrganic ChemicalsSelection GeneticPredatorFinlandmedia_commonMultidisciplinaryPigmentationEcologyFledgeGeneral Chemistry3100 General Physics and AstronomyLepidopteraLarvaGeneral BiochemistryCrypsista1181570 Life sciences; biology590 Animals (Zoology)SeasonsNature Communications
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Considerations on the taxonomy and morphology of Microcotyle spp.: redescription of M. erythrini van Beneden & Hesse, 1863 (sensu stricto) (Monog…

2020

AbstractBackgroundMicrocotyle erythrinivan Beneden & Hesse, 1863 (Platyhelminthes: Monogenea) and other closely related species of the genus are often considered as cryptic. Records in hosts other than the type-host with no species confirmation by molecular analyses have contributed to this situation.MethodsGill parasites of five sparid fishes,Boops boops(L.),Pagellus erythrinus(L.),P. acarne(Risso), Dentex dentex(L.) andPagrus pagrus(L.), from the Western Mediterranean off Spain were collected. Specimens ofMicrocotylespp. were characterised both molecularly and morphologically. Partial fragments (domains D1-D3) of the28SrRNA gene and the cytochromecoxidase subunit 1 (cox1) gene were am…

Gills0301 basic medicineMicrocotylePseudocrypsisZoologylcsh:Infectious and parasitic diseasesErythrinusElectron Transport Complex IV03 medical and health sciencesM. isyebiRNA Ribosomal 28SAnimalslcsh:RC109-216PhylogenyM. whittingtoni n. sp.Haptor morphologybiologyClamp morphologyResearchDentex dentexMicrocotyle erythrini (sensu stricto)PagrusBoops boops030108 mycology & parasitologyClassificationbiology.organism_classificationPerciformes030104 developmental biologyInfectious DiseasesHaptorParasitologyTrematodaMonogeneaBoopsParasites & Vectors
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