Modulation of environmental light alters reception and production of visual signals in Nile tilapia

Hornsby, Mark A. W.; Sabbah, Shai; Robertson, R. Meldrum; Hawryshyn, Craig W.

doi:10.1242/jeb.081331

Cited by 28 publications

(38 citation statements)

References 62 publications

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“…This agrees with developmental plasticity demonstrated in other fishes such as the black bream (Shand et al 2008). The only study to examine adult plasticity showed that adult tilapia were not plastic to altered lighting environments (Hornsby et al 2013). This lack of adult plasticity is similar to studies of the South American species Aequidens pulcher, which found no shifts in photoreceptor sensitivities when fish were reared under different colored lights in the lab (Wagner and Kroger 2005).…”

Section: Tinbergen Question 3: How Does the Trait Develop In An Inmentioning

confidence: 99%

Proximate and ultimate causes of variable visual sensitivities: Insights from cichlid fish radiations

Carleton

Dalton

Escobar‐Camacho

et al. 2016

Genesis

127

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Animals vary in their sensitivities to different wavelengths of light. Sensitivity differences can have fitness implications in terms of animals’ ability to forage, find mates and avoid predators. As a result, visual systems are likely selected to operate in particular lighting environments and for specific visual tasks. This review focuses on cichlid vision, as cichlids have diverse visual sensitivities, and considerable progress has been made in determining the genetic basis for this variation. We describe both the proximate and ultimate mechanisms shaping cichlid visual diversity using the structure of Tinbergen’s four questions. We describe 1) the molecular mechanisms that tune visual sensitivities including changes in opsin sequence and expression; 2) the evolutionary history of visual sensitivity across the African cichlid flocks; 3) the ontological changes in visual sensitivity and how modifying this developmental program alters sensitivities among species; and 4) the fitness benefits of spectral tuning mechanisms with respect to survival and mating success. We further discuss progress to unravel the gene regulatory networks controlling opsin expression and suggest that a simple genetic architecture contributes to the lability of opsin gene expression. Finally, we identify unanswered questions including whether visual sensitivities are experiencing selection, and whether similar spectral tuning mechanisms shape visual sensitivities of other fishes.

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Section: Tinbergen Question 3: How Does the Trait Develop In An Inmentioning

confidence: 99%

Proximate and ultimate causes of variable visual sensitivities: Insights from cichlid fish radiations

Carleton

Dalton

Escobar‐Camacho

et al. 2016

Genesis

127

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“…The light environment is a factor known to drive both the reception and production of visual signals of fishes (Hornsby et al 2013;Hurtado-Gonzales et al 2014;Shin and Choi 2014;Terai et al 2006;Tezuka et al 2014). Indeed, the present study showed that the spectral sensitivities of P. h. himantegus and P. h. chii are distinct: P. h. himantegus is more sensitive than P. h. chii to longer wavelength light, while it is less sensitive than P. h. chii at shorter wavelengths.…”

Section: Discussionmentioning

confidence: 47%

Differentiation of visual spectra and nuptial colorations of two Paratanakia himantegus subspecies (Cyprinoidea: Acheilognathidae) in response to the distinct photic conditions of their habitats

Chang

Shao

et al. 2015

Zool. Stud.

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Background: Vision, an important sensory modality of many animals, exhibits plasticity in that it adapts to environmental conditions to maintain its sensory efficiency. Nuptial coloration is used to attract mates and hence should be tightly coupled to vision. In Taiwan, two closely related bitterlings (Paratanakia himantegus himantegus and Paratanakia himantegus chii) with different male nuptial colorations reside in different habitats. We compared the visual spectral sensitivities of these subspecies with the ambient light spectra of their habitats to determine whether their visual abilities correspond with photic parameters and correlate with nuptial colorations. Results: The electroretinogram (ERG) results revealed that the relative spectral sensitivity of P. h. himantegus was higher at 670 nm, but lower at 370 nm, than the sensitivity of P. h. chii. Both bitterlings could perceive and reflect UV light, but the UV reflection patterns differed between genders. Furthermore, the relative irradiance intensity of the light spectra in the habitat of P. h. himantegus was higher at long wavelengths (480-700 nm), but lower at short wavelengths (350-450 nm), than the light spectra in the habitats of P. h. chii.

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“…The photosensitivity peaks present in the UV (380 nm) and middlewavelength (480 nm) regions were close to the maximum absorbances (λ max ) of the tilapia retinal cone photopigments (SWS1, 360 nm; RH2b, 472 nm) (Spady et al, 2006). To better understand the interaction between photopigments, the visual pigment templates of SWS1 and RH2b were fitted to the erythrophore action spectrum plot (Govardovskii et al, 2000;Sabbah et al, 2012;Hornsby et al, 2013). Because of the opposing effects elicited by these two photopigments, a neutral area of the antagonistic interaction is suggested to be located in the spectral region near 440-460 nm, which is within the overlapping area of the α-bands (the primary absorption peaks) of these two photopigments.…”

Section: Action Spectrum Of Erythrophoresmentioning

confidence: 99%

“…The spectral characteristics of each pigment have been well-established from absorbance spectra of in vitro reconstituted proteins and from in situ microspectrophotometry (MSP) measurement (Spady et al, 2006;Carleton et al, 2008;Lisney et al, 2010). Based on reported sensitivity peaks of tilapia cone pigments (Spady et al, 2006), absorption templates were used to fit the photosensitivity curve using a least-squares fit as described previously (Govardovskii et al, 2000;Anderson et al, 2010;Hornsby et al, 2013). In the action spectrum curve of tilapia erythrophores, two peaks present at 380 and 480 nm were close to the maximum absorbances (λ max ) of the retinal cone photopigments (SWS1, 360 nm; RH2b, 472 nm; with 11-cisretinal; Spady et al, 2006).…”

Section: Curve Fittingmentioning

confidence: 99%

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Functional characterisation of the chromatically antagonistic photosensitive mechanism of erythrophores in the tilapiaOreochromis niloticus

Chen

Xiao

Troje

et al. 2015

Journal of Experimental Biology

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Non-visual photoreceptors with diverse photopigments allow organisms to adapt to changing light conditions. Whereas visual photoreceptors are involved in image formation, non-visual photoreceptors mainly undertake various non-image-forming tasks. They form specialised photosensory systems that measure the quality and quantity of light and enable appropriate behavioural and physiological responses. Chromatophores are dermal non-visual photoreceptors directly exposed to light and they not only receive ambient photic input but also respond to it. These specialised photosensitive pigment cells enable animals to adjust body coloration to fit environments, and play an important role in mate choice, camouflage and ultraviolet (UV) protection. However, the signalling pathway underlying chromatophore photoresponses and the physiological importance of chromatophore colour change remain under-investigated. Here, we characterised the intrinsic photosensitive system of red chromatophores (erythrophores) in tilapia. Like some nonvisual photoreceptors, tilapia erythrophores showed wavelengthdependent photoresponses in two spectral regions: aggregations of inner pigment granules under UV and short-wavelengths and dispersions under middle-and long-wavelengths. The action spectra curve suggested that two primary photopigments exert opposite effects on these lightdriven processes: SWS1 (short-wavelength sensitive 1) for aggregations and RH2b (rhodopsin-like) for dispersions. Both western blot and immunohistochemistry showed SWS1 expression in integumentary tissues and erythrophores. The membrane potential of erythrophores depolarised under UV illumination, suggesting that changes in membrane potential are required for photoresponses. These results suggest that SWS1 and RH2b play key roles in mediating intrinsic erythrophore photoresponses in different spectral ranges and this chromatically dependent antagonistic photosensitive mechanism may provide an advantage to detect subtle environmental photic change.

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Modulation of environmental light alters reception and production of visual signals in Nile tilapia

Cited by 28 publications

References 62 publications

Proximate and ultimate causes of variable visual sensitivities: Insights from cichlid fish radiations

Proximate and ultimate causes of variable visual sensitivities: Insights from cichlid fish radiations

Differentiation of visual spectra and nuptial colorations of two Paratanakia himantegus subspecies (Cyprinoidea: Acheilognathidae) in response to the distinct photic conditions of their habitats

Functional characterisation of the chromatically antagonistic photosensitive mechanism of erythrophores in the tilapiaOreochromis niloticus

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