Retinal specialization through spatially varying cell densities and opsin coexpression in cichlid fish

Dalton, Brian E.; Busserolles, Fanny de; Marshall, N. Justin; Carleton, Karen L.

doi:10.1242/jeb.149211

Cited by 41 publications

(70 citation statements)

References 56 publications

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“…Different visual pigments may be co‐expressed within the same photoreceptor and mixed to differing amounts, potentially to broaden or tune spectral sensitivity or representing transition phases in lifecycle (Lythgoe, ; Hawryshyn & Harosi, ; Hawryshyn et al ., ). For instance, in fresh water, cichlids were found to co‐express cone opsins in both their single (Dalton et al ., ) and double cones (Dalton et al ., ) resulting in broadened spectra to potentially increase achromatic contrast detection. Also, marine fishes such as the yellowfin tuna Thunnus albacares (Bonnaterre 1788) (Loew et al ., ) and starry flounder, Platichthys stellatus (Pallas 1787) (Savelli et al ., ) co‐express multiple opsin pigments during development, but the functionality of this remains elusive.…”

Section: Reef Fishes Colour Visionmentioning

confidence: 99%

“…For instance, in fresh water, cichlids were found to co-express cone opsins in both their single (Dalton et al, 2017) and double cones (Dalton et al, 2014) resulting in broadened spectra to potentially increase achromatic contrast detection. Also, marine fishes such as the yellowfin tuna Thunnus albacares (Bonnaterre 1788) (Loew et al, 2002) and starry flounder, Platichthys stellatus (Pallas 1787) (Savelli et al, 2018) co-express multiple opsin pigments during development, but the functionality of this remains elusive.…”

Section: Visual Pigment Co-expressionmentioning

confidence: 99%

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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%

Section: Visual Pigment Co-expressionmentioning

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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“…Studies using L. goodei (Fuller & Claricoates, ) and cichlids (Nandamuri et al, ) that have indicated plasticity in opsin expression reported significant changes in opsin transcripts, measured by qPCR, within 3 days of exposure to new light regimes. Changes in LWS opsin transcript expression within cones has also been observed by in situ hybridization in cichlids after 6 months of light treatment (Dalton et al, ) and by immunolabelling of LWS opsin in M. atlantica after 4 months of treatment (Schweikert & Grace, ). Whether these changes had already occurred prior to these sampling events is unknown.…”

Section: Discussionmentioning

confidence: 71%

“…Besides genetically programmed opsin switches that occur during retinal development, studies on black bream Acanthopagrus butcheri (Munro 1949) (Shand et al, ), cichlids (Dalton et al, ; Härer et al, ; Nandamuri et al, ), bluefin killifish Lucania goodei Jordan 1880 (Fuller & Claricoates, ), guppies Poecilia reticulata Peters 1859 (Sakai et al, ) and Atlantic tarpon Megalops atlanticus Valenciennes 1847 (Schweikert & Grace, ) have shown plasticity in opsin gene expression in response to changes in the light environment. In guppies (Sakai et al, ) and the M. atlanticus (Schweikert & Grace, ), which seem to upregulate opsin gene products to match the dominant wavelengths of new spectral backgrounds, behavioural and electroretinogram observations suggest enhanced sensitivity to the prevalent spectrum.…”

Section: Introductionmentioning

confidence: 99%

Light exposure during embryonic and yolk‐sac alevin development of Chinook salmon Oncorhynchus tshawytscha does not alter the spectral phenotype of photoreceptors

Flamarique

2018

Journal of Fish Biology

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Colour vision is mediated by the expression of different visual pigments in photoreceptors of the vertebrate retina. Each visual pigment is a complex of a protein (opsin) and a vitamin A chromophore; alterations to either component affects visual pigment absorbance and, potentially, the visual capabilities of an animal. Many species of fish undergo changes in opsin expression during retinal development. In the case of salmonid fishes the single cone photoreceptors undergo a switch in opsin expression from SWS1 (ultraviolet sensitive) to SWS2 (blue‐light sensitive) starting at the yolk‐sac alevin stage, around the time when they first experience light. Whether light may initiate this event or produce a plastic response in the various photoreceptors is unknown. In this study, Chinook salmon Oncorhynchus tshawytscha were exposed to light from the embryonic (5 days prior to hatching) into the yolk sac alevin (25 days post hatching) stage and the spectral phenotype of photoreceptors assessed with respect to that of unexposed controls by in situ hybridization with opsin riboprobes. Light exposure did not change the spectral phenotype of photoreceptors, their overall morphology or spatial arrangement. These results concur with those from a variety of fish species and suggest that plasticity in photoreceptor spectral phenotype via changes in opsin expression may not be a widespread occurrence among teleosts.

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“…Cone‐specific proportional expression | Proportional normalization for the opsins was also employed using cone type‐specific normalization for single cones (SC: SWS1, SWS2A, SWS2B ) and double cones (DC: RH2A, RH2B, LWS ), calculated as a per cent of all opsins within that cell type. Although localization of opsin expression by cone type is not known specifically for this species, microspectrophotometry and fluorescent in situ hybridization done in other African cichlids have all shown this opsin expression pattern in the single and double cones (Carleton et al, ; Dalton et al, ; Dalton, Loew, Cronin, & Carleton, ). The fraction of single cone opsins made up by a particular opsin is:

f_{opsin, SC} = \frac{T_{opsin}}{T_{S W S 1} + T_{S W S 2 B} + T_{S W S 2 A}}

…”

Section: Methodsmentioning

confidence: 97%

Diurnal variation in opsin expression and common housekeeping genes necessitates comprehensive normalization methods for quantitative real‐time PCR analyses

Yourick

Sandkam

Gammerdinger

et al. 2019

Molecular Ecology Resources

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To determine the visual sensitivities of an organism of interest, quantitative reverse transcription–polymerase chain reaction (qRT–PCR) is often used to quantify expression of the light‐sensitive opsins in the retina. While qRT–PCR is an affordable, high‐throughput method for measuring expression, it comes with inherent normalization issues that affect the interpretation of results, especially as opsin expression can vary greatly based on developmental stage, light environment or diurnal cycles. We tested for diurnal cycles of opsin expression over a period of 24 hr at 1‐hr increments and examined how normalization affects a data set with fluctuating expression levels using qRT–PCR and transcriptome data from the retinae of the cichlid Pelmatolapia mariae. We compared five methods of normalizing opsin expression relative to (a) the average of three stably expressed housekeeping genes (Ube2z, EF1‐α and β‐actin), (b) total RNA concentration, (c) GNAT2, (the cone‐specific subunit of transducin), (d) total opsin expression and (e) only opsins expressed in the same cone type. Normalizing by proportion of cone type produced the least variation and would be best for removing time‐of‐day variation. In contrast, normalizing by housekeeping genes produced the highest daily variation in expression and demonstrated that the peak of cone opsin expression was in the late afternoon. A weighted correlation network analysis showed that the expression of different cone opsins follows a very similar daily cycle. With the knowledge of how these normalization methods affect opsin expression data, we make recommendations for designing sampling approaches and quantification methods based upon the scientific question being examined.

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Retinal specialization through spatially varying cell densities and opsin coexpression in cichlid fish

Cited by 41 publications

References 56 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

Light exposure during embryonic and yolk‐sac alevin development of Chinook salmon Oncorhynchus tshawytscha does not alter the spectral phenotype of photoreceptors

Diurnal variation in opsin expression and common housekeeping genes necessitates comprehensive normalization methods for quantitative real‐time PCR analyses

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