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

Nokelainen, Ossi; Maynes, Ruth; Mynott, Sara; Price, Natasha; Stevens, Martin

doi:10.1111/1365-2435.13280

Cited by 42 publications

(56 citation statements)

References 88 publications

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“…Ontogenetic changes are likely to override such plasticity longer term, as adult European lobsters are much less variable than juveniles. Such shifts from plastic camouflage to ontogenetic changes in coloration have been observed in other marine crustaceans (16,68). These ontogenetic shifts in coloration correspond to improved camouflage across the range of environments experienced by adults (68).…”

Section: Discussionsupporting

confidence: 60%

“…Such shifts from plastic camouflage to ontogenetic changes in coloration have been observed in other marine crustaceans (16,68). These ontogenetic shifts in coloration correspond to improved camouflage across the range of environments experienced by adults (68). Consequently, the timing of rearing individuals on different backgrounds relative to the timing of release needs careful thought in order to maximise any applied benefits of camouflage for stocking.…”

Section: Discussionsupporting

confidence: 60%

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Using camouflage for conservation: colour change in juvenile European lobster

Mynott

Daniels

Widdicombe

et al. 2018

Preprint

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25Changes in coloration enable animals to refine their camouflage to match different 26 visual environments. Such plasticity provides ecological benefits and could 27 potentially be exploited to support conservation or stock enhancement efforts. One 28 application could be ensuring that hatchery-reared animals, reared to stock wild 29 populations, are appropriately matched to their environment on release. European 30 lobster (Homarus gammarus) hatcheries aim to restock or enhance local lobster 31 populations by rearing juveniles through their most vulnerable stages, then releasing 32 them into the wild. However, little consideration has been given to their camouflage 33 and the implications of matching individuals to their release site. This study assesses 34 to what extent juvenile lobsters can change coloration to match their background and 35 whether hatchery practices could be altered to enhance lobster camouflage . We test 36 this by switching individuals between black or white backgrounds in the laboratory 37 and monitoring their coloration over time. Our work demonstrates the capacity of 38 juvenile lobsters to change lightness in response to their surroundings. We show that 39 juvenile lobsters are capable of small changes in luminance (perceived lightness) to 40 better match their background over 2-3 weeks. These changes potentially 41 correspond to improved camouflage, based on a model of predator (European 42 pollack, Pollachius pollachius) vision. However, over a longer period (5 weeks), 43 lobsters maintained on either background converged on the same darker coloration, 44suggesting that lobsters also experience changes in appearance associated with 45 ontogeny. By refining the approaches used here, there is potential for hatcheries to 46 rear lobsters on backgrounds that better match their release site. However, such release timing (which varies between stocking programmes). This study highlights 49 the potential to use colour change in stocking and aquaculture, as well as gaps that 50 could be addressed through further research in this area. 51 52 53 54 Background matching is one of the most widely used anti-predator defence 55 strategies in nature (1), with many species using colours and patterns to match their 56 surroundings and avoid detection and predation. In a wide range of taxa, both 57 terrestrial and aquatic, camouflage can be achieved through plastic changes in 58 appearance (2,3). This enables animals to respond to either fast and unpredictable 59 changes in the visual environment through rapid (seconds and minutes) colour 60 change, or slower and more predictable environmental change with gradual (hours, 61 days, and weeks) appearance changes (4). One of the most widely studied groups, 62 particularly in terms of the mechanisms and functions of colour change, are the 63 crustaceans (3,5). Many crustacean species employ camouflage to conceal 64 themselves from predators and several have been shown to change colour to better 65match their background, including crabs (6-8), prawns (9,1...

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Section: Discussionsupporting

confidence: 60%

Section: Discussionsupporting

confidence: 60%

Using camouflage for conservation: colour change in juvenile European lobster

Mynott

Daniels

Widdicombe

et al. 2018

Preprint

Self Cite

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“…The use of human observers via online “games” has been recently used in camouflage studies in birds and their eggs (Troscianko, Wilson‐Aggarwal, Griffiths, Spottiswoode, & Stevens, ), as well as crabs (Nokelainen, Maynes, Mynott, Price, & Stevens, ). Similar citizen science approach has also previously been used to study disruptive coloration with, for example, computer‐generated moth images (Fraser, Callahan, Klassen, & Sherratt, ), and detection and learning of camouflage strategies (Troscianko, Lown, Hughes, & Stevens, ) and to quantify the appearance of camouflaged prey (Troscianko, Skelhorn, & Stevens, ).…”

Section: Methodsmentioning

confidence: 99%

“…The use of human observers via online "games" has been recently used in camouflage studies in birds and their eggs (Troscianko, Wilson-Aggarwal, Griffiths, Spottiswoode, & Stevens, 2017), as well as crabs (Nokelainen, Maynes, Mynott, Price, & Stevens, 2019).…”

Section: Human Observersmentioning

confidence: 99%

Gray plumage color is more cryptic than brown in snowy landscapes in a resident color polymorphic bird

Koskenpato

Lehikoinen

Lindstedt

et al. 2020

Ecology and Evolution

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Camouflage may promote fitness of given phenotypes in different environments. The tawny owl (Strix aluco) is a color polymorphic species with a gray and brown morph resident in the Western Palearctic. A strong selection pressure against the brown morph during snowy and cold winters has been documented earlier, but the selection mechanisms remain unresolved. Here, we hypothesize that selection favors the gray morph because it is better camouflaged against predators and mobbers in snowy conditions compared to the brown one. We conducted an online citizen science experiment where volunteers were asked to locate a gray or a brown tawny owl specimen from pictures taken in snowy and snowless landscapes. Our results show that the gray morph in snowy landscapes is the hardest to detect whereas the brown morph in snowy landscapes is the easiest to detect. With an avian vision model, we show that, similar to human perceivers, the brown morph is more conspicuous than the gray against coniferous tree trunks for a mobbing passerine. We suggest that with better camouflage, the gray morph may avoid mobbers and predators more efficiently than the brown morph and thus survive better in snowy environments. As winters are getting milder and shorter in the species range, the selection periods against brown coloration may eventually disappear or shift poleward.

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“…At least observationally, there are clearly many examples of excellent and highly specialized camouflage phenotypes [3,5,7,15]. Similarly, there are cases that have been suggested as examples of generalist camouflage, including the desert spiny lizard [9], some Aegean wall lizard morphs [29], shore crabs [30,31], and some moth [10] and grasshopper [32] species. These putative generalist species often seem to have relatively drab coloration, which is often greenish-brownish to human observers and appears as if it would broadly match more than one background ( figure 3).…”

Section: Evidence In Nature?mentioning

confidence: 99%

Imperfect camouflage: how to hide in a variable world?

2019

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Camouflage is an important anti-predator strategy for many animals and is traditionally thought of as being tightly linked to a specific visual background. While much work focuses on optimizing camouflage against one background, this may not be relevant for many species and contexts, as animals may encounter many different habitats throughout their lives due to temporal and spatial variation in their environment. How should camouflage be optimized when an animal or object is seen against multiple visual backgrounds? Various solutions may exist, including colour change to match new environments or use of behaviour to maintain crypsis by choosing appropriate substrates. Here, we focus on a selection of approaches under a third alternative strategy: animals may adopt (over evolution) camouflage appearances that represent an optimal solution against multiple visual scenes. One approach may include a generalist or compromise strategy, where coloration matches several backgrounds to some extent, but none closely. A range of other camouflage types, including disruptive camouflage, may also provide protection in multiple environments. Despite detailed theoretical work determining the plausibility of compromise camouflage and elucidating the conditions under which it might evolve, there is currently mixed experimental evidence supporting its value and little evidence of it in natural systems. In addition, there remain many questions including how camouflage strategies should be defined and optimized, and how they might interact with other types of crypsis and defensive markings. Overall, we provide a critical overview of our current knowledge about how camouflage can enable matching to multiple backgrounds, discuss important challenges of working on this question and make recommendations for future research.

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

Cited by 42 publications

References 88 publications

Using camouflage for conservation: colour change in juvenile European lobster

Using camouflage for conservation: colour change in juvenile European lobster

Gray plumage color is more cryptic than brown in snowy landscapes in a resident color polymorphic bird

Imperfect camouflage: how to hide in a variable world?

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