Spectral Tuning in the Eyes of Deep-Sea Lanternfishes (Myctophidae): A Novel Sexually Dimorphic Intra-Ocular Filter

Busserolles, Fanny de; Hart, Nathan S.; Hunt, David M.; Marshall, N. Justin; Clarke, Michael; Hahne, Dorothee; Collin, Shaun P.

doi:10.1159/000371652

Cited by 19 publications

(28 citation statements)

References 98 publications

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“…The absorption of different reef-fish lenses and corneas and the short wavelength cut-off of combined ocular media often sharpen and shift spectral sensitivities of photoreceptors from the visual pigment absorbance alone (Figure 11(c)). In a few fish species, there are also retinal inclusions around the photoreceptors in the light path that provide further spectral sensitivity tuning (Collin & Potter, 2000;de Busserolles et al, 2015). These are very poorly understood in reef fishes and relatives (Fineran & Nicol, 1974).…”

Section: Reef Fishes Colour Visionmentioning

confidence: 99%

Colours and colour vision in reef fishes: Past, present and future research directions

Marshall

Cortesi

Busserolles

et al. 2018

Journal of Fish Biology

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Many fishes, both freshwater or marine, have colour vision that may outperform humans. As a result, to understand the behavioural tasks that vision enables; including mate choice, feeding, agonistic behaviour and camouflage, we need to see the world through a fish's eye. This includes quantifying the variable light environment underwater and its various influences on vision. As well as rapid loss of light with depth, light attenuation underwater limits visual interaction to metres at most and in many instances, less than a metre. We also need to characterize visual sensitivities, fish colours and behaviours relative to both these factors. An increasingly large set of techniques over the past few years, including improved photography, submersible spectrophotometers and genetic sequencing, have taken us from intelligent guesswork to something closer to sensible hypotheses. This contribution to the special edition on the Ecology of Fish Senses under a shifting environment first reviews our knowledge of fish colour vision and visual ecology, past, present and very recent, and then goes on to examine how climate change may impinge on fish visual capability. The review is limited to mostly colour vision and to mostly reef fishes. This ignores a large body of work, both from other marine environments and freshwater systems, but the reef contains examples of many of the challenges to vision from the aquatic environment. It is also a concentrate of life, perhaps the most specious and complex on earth, suffering now catastrophically from the consequences of our lack of action on climate change. A clear course of action to prevent destruction of this habitat is the need to spend more time in it, in the study of it and sharing it with those not fortunate enough to see coral reefs first‐hand. Sir David Attenborough on The Great Barrier Reef: “Do we really care so little about the Earth upon which we live that we don't wish to protect one of its greatest wonders from the consequences of our behaviours?”

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Section: Reef Fishes Colour Visionmentioning

confidence: 99%

Colours and colour vision in reef fishes: Past, present and future research directions

Marshall

Cortesi

Busserolles

et al. 2018

Journal of Fish Biology

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“…In an attempt to explain the remaining deviations between the normalised absorbance curve of a photoreceptor and the pure A 1 /A 2 visual pigment template, a mixed chromophore model was used (Temple et al, 2010;de Busserolles et al, 2015). The model assumed that each photoreceptor contained only one opsin, but possibly a varying percentage of A 1 -and A 2 -based chromophores.…”

Section: Analysis Of Absorbance Spectramentioning

confidence: 99%

Spatial resolving power and spectral sensitivity of the saltwater crocodile, Crocodylus porosus, and the freshwater crocodile, Crocodylus johnstoni

Nagloo

Collin

Hemmi

et al. 2016

Journal of Experimental Biology

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Crocodilians are apex amphibious predators that occupy a range of tropical habitats. In this study, we examined whether their semiaquatic lifestyle and ambush hunting mode are reflected in specific adaptations in the peripheral visual system. Design-based stereology and microspectrophotometry were used to assess spatial resolving power and spectral sensitivity of saltwater (Crocodylus porosus) and freshwater crocodiles (Crocodylus johnstoni). Both species possess a foveal streak that spans the naso-temporal axis and mediates high spatial acuity across the central visual field. The saltwater crocodile and freshwater crocodile have a peak spatial resolving power of 8.8 and 8.0 cycles deg, respectively. Measurement of the outer segment dimensions and spectral absorbance revealed five distinct photoreceptor types consisting of three single cones, one twin cone and a rod. The three single cones (saltwater/freshwater crocodile) are violet (424/426 nm λ max ), green (502/510 nm λ max ) and red (546/ 554 nm λ max ) sensitive, indicating the potential for trichromatic colour vision. The visual pigments of both members of the twin cones have the same λ max as the red-sensitive single cone and the rod has a λ max at 503/510 nm (saltwater/freshwater). The λ max values of all types of visual pigment occur at longer wavelengths in the freshwater crocodile compared with the saltwater crocodile. Given that there is a greater abundance of long wavelength light in freshwater compared with a saltwater environment, the photoreceptors would be more effective at detecting light in their respective habitats. This suggests that the visual systems of both species are adapted to the photic conditions of their respective ecological niche.

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“…Previous studies investigating lanternfish diversification in open‐ocean environments have focused on their bioluminescent communication (Davis, Holcroft, Wiley, Sparks, & Smith, 2014; Davis, Sparks, & Smith, 2016), vision (de Busserolles et al, 2015), and jaw size (Martin & Davis, 2016); while others have examined diversification in relation to historical oceanic partitioning events (Denton, 2018). These previous works offer an insight into lanternfish speciation and provoke new questions, inspiring a need for deeper understanding of diversification in this abundant and diverse group.…”

Section: Introductionmentioning

confidence: 99%

The evolution of specialized dentition in the deep‐sea lanternfishes (Myctophiformes)

Martin

Davis

2020

Journal of Morphology

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Spectral Tuning in the Eyes of Deep-Sea Lanternfishes (Myctophidae): A Novel Sexually Dimorphic Intra-Ocular Filter

Cited by 19 publications

References 98 publications

Colours and colour vision in reef fishes: Past, present and future research directions

Colours and colour vision in reef fishes: Past, present and future research directions

Spatial resolving power and spectral sensitivity of the saltwater crocodile, Crocodylus porosus, and the freshwater crocodile, Crocodylus johnstoni

The evolution of specialized dentition in the deep‐sea lanternfishes (Myctophiformes)

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