Eye-Size Variability in Deep-Sea Lanternfishes (Myctophidae): An Ecological and Phylogenetic Study

Busserolles, Fanny de; Fitzpatrick, John L.; Paxton, John; Marshall, N. Justin; Collin, Shaun P.

doi:10.1371/journal.pone.0058519

Cited by 50 publications

(68 citation statements)

References 53 publications

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“…Seapy (1990) found that larger species offshore of Oahu migrated to deeper waters during the daytime. Similar trends of larger taxa with depth have been found in other mesopelagic zooplankton (Dai et al 2017), and larger eyes relative to body size are thought to in crease photon capture (and hence detection of predators and prey) in deeper dwelling mesopelagic fishes (de Busserolles et al 2013). …”

Section: Deep Water Diurnal Migrationsupporting

confidence: 59%

Vertical distribution and diurnal migration of atlantid heteropods

Wall-Palmer¹,

Metcalfe²,

Leng³

et al. 2018

Mar. Ecol. Prog. Ser.

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Section: Deep Water Diurnal Migrationsupporting

confidence: 59%

Vertical distribution and diurnal migration of atlantid heteropods

Wall-Palmer¹,

Metcalfe²,

Leng³

et al. 2018

Mar. Ecol. Prog. Ser.

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“…L. alatus and L. parvicauda, indicating a higher acuity in the centro-lateral visual field thereby allowing the fish to perceive signals in a large part of its monocular field of view, suggesting that these species are visual generalists. In addition to the generalist specialization, L. parvicauda does not appear to possess a very sensitive visual system due to its relatively small eyes [de Busserolles et al, 2013] and low summation ratios (around 20: 1 in the peak area and 50: 1 in the periphery) compared to other myctophids (i.e. M. brachygnathum 200: 1 in the peak area and 500: 1 in the non-specialized region) [de Busserolles et al, 2014b;this study].…”

Section: Ecological Significance Of the Retinal Specializations In Lamentioning

confidence: 89%

“…Furthermore, most species possessing an elongated area are also known to be surface migrants and have been recorded in the first few metres of water at night (i.e. Myctophum sp., Symbolophorus sp., D. laternatus [de Busserolles et al, 2013]), where a weak visual horizon would be formed by the downwelling light emitted by the moon and stars or by the air-water interface, explaining the need for a streaklike elongated area in these species.…”

Section: Inter-specific Differences In Retinal Specialisations In Lanmentioning

confidence: 99%

“…photophores and luminous organs) thought to play several different roles (camouflage, distraction, illumination and intra-and inter-specific communication) [Case et al, 1977;Edwards and Herring, 1977]. Myctophids also show marked intra-and interspecific variation in the depths they occupy [Karnella, 1987], their migration patterns [Watanabe et al, 1999] and the location of their luminous organs [Nafpaktitis and Nafpaktitis, 1969;Paxton, 1972;Nafpaktitis et al, 1977Nafpaktitis et al, , 1978Zahuranec, 2000;Herring, 2007;de Busserolles et al, 2013]. Recently, marked differences in the visual system of this large group of fishes have been revealed [de Busserolles et al, 2013[de Busserolles et al, , 2014a, including large variations in photoreceptor distribution across the retina [de Busserolles et al, 2014b].…”

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confidence: 99%

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Retinal Ganglion Cell Distribution and Spatial Resolving Power in Deep-Sea Lanternfishes (Myctophidae)

2014

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Topographic analyses of retinal ganglion cell density are very useful in providing information about the visual ecology of a species by identifying areas of acute vision within the visual field (i.e. areas of high cell density). In this study, we investigated the neural cell distribution in the ganglion cell layer of a range of lanternfish species belonging to 10 genera. Analyses were performed on wholemounted retinas using stereology. Topographic maps were constructed of the distribution of all neurons and both ganglion and amacrine cell populations in 5 different species from Nissl-stained retinas using cytological criteria. Amacrine cell distribution was also examined immunohistochemically in 2 of the 5 species using anti-parvalbumin antibody. The distributions of both the total neuron and the amacrine cell populations were aligned in all of the species examined, showing a general increase in cell density toward the retinal periphery. However, when the ganglion cell population was topographically isolated from the amacrine cell population, which comprised up to 80% of the total neurons within the ganglion cell layer, a different distribution was revealed. Topographic maps of the true ganglion cell distribution in 18 species of lanternfishes revealed well-defined specializations in different regions of the retina. Different species possessed distinct areas of high ganglion cell density with respect to both peak density and the location and/or shape of the specialized acute zone (i.e. elongated areae ventro-temporales, areae temporales and large areae centrales). The spatial resolving power was calculated to be relatively low (varying from 1.6 to 4.4 cycles per degree), indicating that myctophids may constitute one of the less visually acute groups of deep-sea teleosts. The diversity in retinal specializations and spatial resolving power within the family is assessed in terms of possible ecological functions and evolutionary history.

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“…Like most mesopelagic fishes, lanternfishes (Myctophidae) possess several visual adaptations for life in the mesopelagic zone that serve to increase the sensitivity of the eye and optimise photon capture [de Busserolles et al, 2013[de Busserolles et al, , 2014a. Lanternfishes generally lack cones and possess a single rod photoreceptor class with a peak spectral absorption tuned to the blue-green region of the visible spectrum [Partridge et al, 1992;Douglas and Partridge, 1997;Turner et al, 2009].…”

mentioning

confidence: 99%

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

Busserolles¹,

Hart²,

Hunt³

et al. 2015

Brain Behav Evol

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Deep-sea fishes possess several adaptations to facilitate vision where light detection is pushed to its limit. Lanternfishes (Myctophidae), one of the world's most abundant groups of mesopelagic fishes, possess a novel and unique visual specialisation, a sexually dimorphic photostable yellow pigmentation, constituting the first record of a visual sexual dimorphism in any non-primate vertebrate. The topographic distribution of the yellow pigmentation across the retina is species specific, varying in location, shape and size. Spectrophotometric analyses reveal that this new retinal specialisation differs between species in terms of composition and acts as a filter, absorbing maximally between 356 and 443 nm. Microspectrophotometry and molecular analyses indicate that the species containing this pigmentation also possess at least 2 spectrally distinct rod visual pigments as a result of a duplication of the Rh1 opsin gene. After modelling the effect of the yellow pigmentation on photoreceptor spectral sensitivity, we suggest that this unique specialisation acts as a filter to enhance contrast, thereby improving the detection of bioluminescent emissions and possibly fluorescence in the extreme environment of the deep sea. The fact that this yellow pigmentation is species specific, sexually dimorphic and isolated within specific parts of the retina indicates an evolutionary pressure to visualise prey/predators/mates in a particular part of each species' visual field.

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Eye-Size Variability in Deep-Sea Lanternfishes (Myctophidae): An Ecological and Phylogenetic Study

Cited by 50 publications

References 53 publications

Vertical distribution and diurnal migration of atlantid heteropods

Vertical distribution and diurnal migration of atlantid heteropods

Retinal Ganglion Cell Distribution and Spatial Resolving Power in Deep-Sea Lanternfishes (Myctophidae)

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

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