Distance-dependent defensive coloration in the poison frog
            <i>Dendrobates tinctorius</i>
            , Dendrobatidae

Barnett, James B.; Michalis, Constantine; Scott‐Samuel, Nicholas E.; Cuthill, Innes C.

doi:10.1073/pnas.1800826115

Cited by 68 publications

(89 citation statements)

References 65 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In fact, studies within this system have even suggested that natural and sexual selection may operate on different aspects of frog coloration, as variation in male brightness, an important component of assortative mating and male–male interactions, is not visible to avian predators (Crothers & Cummings, ). Additionally, there is growing evidence that pattern traits in poison frogs may also be under selection (Barnett, Michalis, Scott‐Samuel, & Cuthill, ; Rojas & Endler, ; Wollenberg, Lötters, Mora‐Ferrer, & Veith, ). Studies of intrapopulation pattern variation in the poison frog Dendrobates tinctorius have demonstrated that certain pattern traits are correlated with movement behavior, suggesting that patterning elements may also be important in determining how aposematic organisms are perceived by predators (Rojas, Devillechabrolle, & Endler, ).…”

Section: Discussionmentioning

confidence: 99%

“…Studies of intrapopulation pattern variation in the poison frog Dendrobates tinctorius have demonstrated that certain pattern traits are correlated with movement behavior, suggesting that patterning elements may also be important in determining how aposematic organisms are perceived by predators (Rojas, Devillechabrolle, & Endler, ). In fact, recent work in D. tinctorius indicates that pattern and color function as an aposematic signal to predators at close range, but are perceived as cryptic when viewed from longer distances (Barnett et al, ). Future work on phenotypic diversity in Malagasy poison frogs should draw on this body of literature and consider the relative roles of natural and sexual selection in shaping phenotypes, as well as the relative contributions of color and pattern to predator avoidance.…”

Section: Discussionmentioning

confidence: 99%

“…Although we observed high degrees of pattern variation on the side and ventral surfaces of frogs in our study (Figures and ), the role of this variation is unknown. Recent work in poison frogs linking patterning elements to movement behavior and detectability by predators (Barnett et al, ; Rojas, Devillechabrolle et al, ) indicates that pattern variation may be equally, or even more, biologically relevant than color variation. Further, evidence that the detectability of different color pattern variants is influenced by the existing light environment (Rojas, Rautiala, & Mappes, ) underscores the importance of incorporating information on both predator sensory abilities and ambient lighting conditions into the characterization of phenotypic variation.…”

Section: Discussionmentioning

confidence: 99%

See 2 more Smart Citations

Phenotypic and genetic diversity in aposematic Malagasy poison frogs (genus Mantella)

Klonoski

Rosenblum

2019

Ecology and Evolution

View full text Add to dashboard Cite

Intraspecific color variation has long fascinated evolutionary biologists. In species with bright warning coloration, phenotypic diversity is particularly compelling because many factors, including natural and sexual selection, contribute to intraspecific variation. To better understand the causes of dramatic phenotypic variation in Malagasy poison frogs, we quantified genetic structure and color and pattern variation across three closely related species, Mantella aurantiaca , Mantella crocea , and Mantella milotympanum . Although our restriction site‐associated DNA (RAD) sequencing approach identified clear genetic clusters, they do not align with current species designations, which has important conservation implications for these imperiled frogs. Moreover, our results suggest that levels of intraspecific color variation within this group have been overestimated, while species diversity has been underestimated. Within major genetic clusters, we observed distinct patterns of variation including: populations that are phenotypically similar yet genetically distinct, populations where phenotypic and genetic breaks coincide, and populations that are genetically similar but have high levels of within‐population phenotypic variation. We also detected admixture between two of the major genetic clusters. Our study suggests that several mechanisms—including hybridization, selection, and drift—are contributing to phenotypic diversity. Ultimately, our work underscores the need for a reevaluation of how polymorphic and polytypic populations and species are classified, especially in aposematic organisms.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Phenotypic and genetic diversity in aposematic Malagasy poison frogs (genus Mantella)

Klonoski

Rosenblum

2019

Ecology and Evolution

View full text Add to dashboard Cite

show abstract

“…Furthermore, that match need only be accurate at the spatial frequency the viewer is sampling at; in other words, as limited by their visual acuity (Caves, Brandley & Johnsen, ). This allows the same pattern to function as camouflage at a distance, but a signal when the intended viewer is close (Endler, , ; Merilaita & Tullberg, ; Bohlin, Tullberg & Merilaita, ; Barnett & Cuthill, ; Barnett, Scott‐Samuel & Cuthill, ; Barnett et al ., ,b, ,b; Barnett, Cuthill & Scott‐Samuel, , ).…”

Section: Exploiting Receiver Psychologymentioning

confidence: 99%

“…If the background has an oriented texture, such as the vertical grain of bark on trees such as oak, then a background‐matching animal has to orient such that its texture matches (Sargent, ; Kang et al ., , ; Barnett et al ., ,b, ,b). This demands the ability to detect the background texture, not necessarily visually because tactile cues may suffice, and orient appropriately.…”

Section: Constraints On Camouflagementioning

confidence: 99%

Camouflage

2019

Self Cite

View full text Add to dashboard Cite

Animal camouflage has long been used to illustrate the power of natural selection, and provides an excellent testbed for investigating the trade‐offs affecting the adaptive value of colour. However, the contemporary study of camouflage extends beyond evolutionary biology, co‐opting knowledge, theory and methods from sensory biology, perceptual and cognitive psychology, computational neuroscience and engineering. This is because camouflage is an adaptation to the perception and cognition of the species (one or more) from which concealment is sought. I review the different ways in which camouflage manipulates and deceives perceptual and cognitive mechanisms, identifying how, and where in the sequence of signal processing, strategies such as transparency, background matching, disruptive coloration, distraction marks, countershading and masquerade have their effects. As such, understanding how camouflage evolves and functions not only requires an understanding of animal sensation and cognition, it sheds light on perception in other species.

show abstract

The effect of pelage, background, and distance on predator detection and the evolution of primate color vision

Moraes

Diniz

Spyrides

et al. 2021

American J Primatol

View full text Add to dashboard Cite

Primates' predators, such as carnivore mammals, usually rely on camouflage to increase proximity to prey and start a predatory attempt. Camouflage depends not only on the color pattern presented by a predator's pelage but also on the background scene in which the hunting takes place. Another factor that influences camouflage effectiveness is prey's color vision since a given camouflage strategy might not work for all visual phenotypes. Still, little research has been made on the effect of primate visual phenotype on predator detection. Here, we investigate the effects of natural pelages, background scenarios, visual phenotypes, and detection distances on predator detection. We used photographs of taxidermized carnivores (ocelots, cougars, and lesser grisons) as detection stimuli, taken in three different natural scenarios (forest, savanna, and grassland), and at two viewing distances (near and far). On a touchscreen monitor, sets of four images (only one containing a hidden animal) were randomly presented to 39 human males (19 dichromats and 20 trichromats). We found that trichromats, when compared to dichromats, present a lower latency and a higher accuracy of carnivore detection for some conditions tested. We also found that pelage color, background scenario, and detection distance interact to influence the effectiveness of camouflage. Our results suggest that trichromacy might be even more advantageous for carnivore detection than thought before, since it facilitates detection of mammals with diverse pelage colorations, in environments with different phytophysiognomies, and at longer distances. We also propose that the higher rates of dichromacy found in modern human societies could have resulted from a relaxation in predation.

show abstract

Distance-dependent defensive coloration in the poison frog Dendrobates tinctorius , Dendrobatidae

Cited by 68 publications

References 65 publications

Phenotypic and genetic diversity in aposematic Malagasy poison frogs (genus Mantella)

Phenotypic and genetic diversity in aposematic Malagasy poison frogs (genus Mantella)

Camouflage

The effect of pelage, background, and distance on predator detection and the evolution of primate color vision

Contact Info

Product

Resources

About