Camouflage through colour change: mechanisms, adaptive value and ecological significance

Duarte, Rafael Cervantes; Flores, Augusto A. V.; Stevens, Martin

doi:10.1098/rstb.2016.0342

Cited by 156 publications

(191 citation statements)

References 55 publications

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“…Our results also showed that the crabs developed more uniform patterning (see also Figure S2). It is not well known what maintains the high colour variation in juvenile crabs, but it may be related to the need to match variable background habitats at spatial scales (Nokelainen, Hubbard et al, ) that are relevant when individuals are small, and/or breaking predator search image formation (Bond & Kamil, ; Duarte et al, ; Karpestam et al, ; Punzalan et al, ). It is plausible that juvenile crabs may also rely on other types of camouflage, such as disruptive coloration (Todd et al, ), and this may be habitat‐specific, with crabs from rock pools favouring disruption and crabs from mudflats tending towards background matching.…”

Section: Discussionmentioning

confidence: 99%

“…The efficacy of camouflage is linked to the similarity of individuals with features of the visual environment (Troscianko, Wilson‐Aggarwal, Spottiswoode, & Stevens, ), and therefore, generally a given phenotype should be effective in hiding individuals in some environments but not in others (Ruxton et al, ; Stevens & Merilaita, ). Importantly, camouflage is often not static because many animals can change appearance over time during their life span, either through reversible plastic changes or via ontogenetic changes (Duarte, Flores, & Stevens, ; Stuart‐Fox & Moussalli, ). Yet, the mechanisms and implications of ontogenetic colour change for survival remain significantly unexplored.…”

Section: Introductionmentioning

confidence: 99%

“…Similar changes for camouflage tuning over days and weeks occur both within and between moults in other groups, such as grasshoppers (Burtt, ; Edelaar, Baños‐Villalba, Escudero, & Rodríguez‐Bernal, ; Peralta‐Rincon, Escudero, & Edelaar, ) and caterpillars (Eacock et al, ). Not only can individuals change their coloration over multiple time‐scales to facilitate camouflage, but many also undergo changes in appearance as a result of ontogeny (Duarte et al, ; Iampietro, ; Jensen & Egnotovich, ; Reid, Abello, Kaiser, & Warman, ; Stevens, ; Styrishave, Rewitz, & Andersen, ; Todd, Qiu, & Chong, ). For example, racer snakes become more uniform in coloration with age, a change that seems to be linked to behaviour and anti‐predator strategies (Creer, ).…”

Section: Introductionmentioning

confidence: 99%

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Improved camouflage through ontogenetic colour change confers reduced detection risk in shore crabs

et al. 2019

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Animals from many taxa, from snakes and crabs to caterpillars and lobsters, change appearance with age, but the reasons why this occurs are rarely tested. We show the importance that ontogenetic changes in coloration have on the camouflage of the green shore crabs ( Carcinus maenas ), known for their remarkable phenotypic variation and plasticity in colour and pattern. In controlled conditions, we reared juvenile crabs of two shades, pale or dark, on two background types simulating different habitats for 10 weeks. In contrast to expectations for reversible colour change, crabs did not tune their background match to specific microhabitats, but instead, and regardless of treatment, all developed a uniform dark green phenotype. This parallels changes in shore crab appearance with age observed in the field. Next, we undertook a citizen science experiment at the Natural History Museum London, where human subjects (“predators”) searched for crabs representing natural colour variation from different habitats, simulating predator vision. In concert, crabs were not hardest to find against their original habitat, but instead, the dark green phenotype was hardest to detect against all backgrounds. The evolution of camouflage can be better understood by acknowledging that the optimal phenotype to hide from predators may change over the life history of many animals, including the utilization of a generalist camouflage strategy. A plain language summary is available for this article.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Improved camouflage through ontogenetic colour change confers reduced detection risk in shore crabs

et al. 2019

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“…Indirect evidence of microhabitat selection for camouflage also exists from field studies of freshwater turtles (Xiao et al, ). Beyond this, many crabs and other crustaceans show size‐/age‐dependent shifts in habitat use that correlate with changes in appearance (usually through ontogeny), and one potential explanation is that this is related to differences in predation risk and camouflage in different habitats (Todd, Qiu & Chong, ; Duarte et al, ).…”

Section: Background Choicementioning

confidence: 99%

The key role of behaviour in animal camouflage

2018

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Animal camouflage represents one of the most important ways of preventing (or facilitating) predation. It attracted the attention of the earliest evolutionary biologists, and today remains a focus of investigation in areas ranging from evolutionary ecology, animal decision-making, optimal strategies, visual psychology, computer science, to materials science. Most work focuses on the role of animal morphology per se, and its interactions with the background in affecting detection and recognition. However, the behaviour of organisms is likely to be crucial in affecting camouflage too, through background choice, body orientation and positioning; and strategies of camouflage that require movement. A wealth of potential mechanisms may affect such behaviours, from imprinting and self-assessment to genetics, and operate at several levels (species, morph, and individual). Over many years there have been numerous studies investigating the role of behaviour in camouflage, but to date, no effort to synthesise these studies and ideas into a coherent framework. Here, we review key work on behaviour and camouflage, highlight the mechanisms involved and implications of behaviour, discuss the importance of this in a changing world, and offer suggestions for addressing the many important gaps in our understanding of this subject.

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“…Prey species may also reduce the risk of predation from visually hunting predators using color defense strategies such as masquerade, crypsis, and aposematism (Booth, ; Caro, Sherratt, & Stevens, ; Cuthill et al., ; Higginson & Ruxton, ; Lichter‐Marck, Wylde, Aaron, Oliver, & Singer, ; Skelhorn, Rowland, Speed, & Ruxton, ; Speed, ). Masquerading prey resemble some inedible objects (at times, objects aversive to their predators, such as bird droppings) in their natural environment and are misidentified by predators, whereas cryptic prey avoid detection by matching the color and pattern of their body with those of the background (Duarte, Flores, & Stevens, ). Aposematic species, on the other hand, are usually chemically defended and therefore are distasteful and unprofitable and advertise their unpalatability through warning coloration to predators that learn to avoid harmful prey (Mappes, Marples, & Endler, ; Mukherjee & Heithaus, ; Stevens & Ruxton, ).…”

Section: Introductionmentioning

confidence: 99%

Evolution of ontogenic change in color defenses of swallowtail butterflies

Gaitonde

Joshi

Kunte

2018

Ecology and Evolution

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Natural selection by visually hunting predators has led to the evolution of color defense strategies such as masquerade, crypsis, and aposematism that reduce the risk of predation in prey species. These color defenses are not mutually exclusive, and switches between strategies with ontogenic development are widespread across taxa. However, the evolutionary dynamics of ontogenic color change are poorly understood. Using comparative phylogenetics, we studied the evolution of color defenses in the complex life cycles of swallowtail butterflies (family Papilionidae). We also tested the relative importance of life history traits, chemical and visual backgrounds, and ancestry on the evolution of protective coloration. We found that vulnerable early‐ and late‐instar caterpillars of species that feed on sparsely vegetated, toxic plants were aposematic, whereas species that feed on densely vegetated, nontoxic plants had masquerading and cryptic caterpillars. Masquerading caterpillars resembled bird droppings at early instars and transitioned to crypsis with an increase in body size at late instars. The immobile pupae—safe from motion‐detecting, visually hunting predators—retained the ancestral cryptic coloration in all lineages, irrespective of the toxic nature of the host plant. Thus, color defense strategy (masquerade, crypsis, or aposematism) at a particular lifestage in the life cycle of swallowtail butterflies was determined by the interaction between life history traits such as body size and motion levels, phytochemical and visual backgrounds, and ancestry. We show that ontogenic color change in swallowtail butterflies is an adaptive response to age‐dependent vulnerability to predation.

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Camouflage through colour change: mechanisms, adaptive value and ecological significance

Cited by 156 publications

References 55 publications

Improved camouflage through ontogenetic colour change confers reduced detection risk in shore crabs

Improved camouflage through ontogenetic colour change confers reduced detection risk in shore crabs

The key role of behaviour in animal camouflage

Evolution of ontogenic change in color defenses of swallowtail butterflies

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