Visual adaptation in Lake Victoria cichlid fishes: depth-related variation of color and scotopic opsins in species from sand/mud bottoms

Terai, Yohey; Miyagi, Ryutaro; Aibara, Mitsuto; Mizoiri, Shinji; Imai, Hiroo; Okitsu, Takashi; Wada, Akimori; Takahashi-Kariyazono, Shiho; Sato, Akie; Tichy, Herbert; Mrosso, Hillary D. J.; Mzighani, Semvua Isa; Okada, Norihiro

doi:10.1186/s12862-017-1040-x

Cited by 31 publications

(29 citation statements)

References 45 publications

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“…Fish visual systems are generally adapted to the overall light available in their environment (Crescitelli, McFall‐Ngai, & Horwitz, ; Lythgoe, ). Therefore, small differences in habitat depth (Stieb et al, ; Terai et al, ) and substrate (Sabbah et al, ) can influence opsin expression according to gradients in available light and environmental reflectance, respectively, leading to diverse photoreceptor spectral sensitivities (Cronin et al, ; Lythgoe et al, ). Within the boundaries of the available light, colour sensitivity may also be shaped by specific behavioural tasks, such as mate choice, conspecific recognition, or foraging (Marshall, Vorobyev, & Siebeck, ; Marshall, ; Marshall & Vorobyev, ; Miyagi et al, ; Sandkam et al, ).…”

Section: Discussionmentioning

confidence: 99%

Cardinalfishes (Apogonidae) show visual system adaptations typical of nocturnally and diurnally active fish

et al. 2019

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Animal visual systems adapt to environmental light on various timescales. In scotopic conditions, evolutionary time‐scale adaptations include spectral tuning to a narrower light spectrum, loss (or inactivation) of visual genes, and pure‐rod or rod‐dominated retinas. Some fishes inhabiting shallow coral reefs may show activity during the day and at night. It is unclear whether these fishes show adaptations typical of exclusively nocturnal or deep‐sea fishes, or of diurnally active shallow‐water species. Here, we investigated visual pigment diversity in cardinalfishes (Apogonidae). Most cardinalfishes are nocturnal foragers, yet they aggregate in multispecies groups in and around coral heads during the day, engaging in social and predator avoidance behaviours. We sequenced retinal transcriptomes of 28 species found on the Great Barrier Reef, assessed the diversity of expressed opsin genes and predicted the spectral sensitivities of resulting photopigments using sequence information. Predictions were combined with microspectrophotometry (MSP) measurements in seven cardinalfish species. Retinal opsin expression was rod opsin (RH1) dominated (>87%), suggesting the importance of scotopic vision. However, all species retained expression of multiple cone opsins also, presumably for colour vision. We found five distinct quantitative expression patterns among cardinalfishes, ranging from short‐wavelength‐shifted to long‐wavelength‐shifted. These results indicate that cardinalfishes are both well adapted to dim‐light conditions and have retained a sophisticated colour vision sense. Other reef fish families also show both nocturnal and diurnal activity while most are strictly one or the other. It will be interesting to compare these behavioural differences across different phylogenetic groups using the criteria and methods developed here.

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Section: Discussionmentioning

confidence: 99%

Cardinalfishes (Apogonidae) show visual system adaptations typical of nocturnally and diurnally active fish

et al. 2019

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“…Since variation in spectral sensitivities is due, to a large extent, to differences in vitamin A 2 content, it is not surprising that, with the notable exception of G. atracaudatus , there was little variation in blue cone sensitivity across species, as the effects of the chromophore are minimal at short wavelengths (Whitmore and Bowmaker 1989). Chromophore-based spectral tuning is characteristic of fish inhabiting long-wavelength-shifted habitats (Whitmore and Bowmaker 1989; Carleton et al 2006; Toyama et al 2008; Hofmann et al 2009; Miyagi et al 2012; Saarinen et al 2012; Weadick et al 2012; Liu et al 2016; Terai et al 2017; Torres-Dowdall et al 2017; Escobar-Camacho et al 2019), and is well suited to the variable light environments of Neotropical freshwater ecosystems, famously among the most diverse in spectra on the planet, from clear fast-running mountain creeks, to muddy ‘white waters’ (from ‘ agua blanca’ , indicating turbid highly scattering brown-tainted waters), and tannin-rich black waters (Wallace 1865; Costa et al 2013; Escobar-Camacho et al 2019). Finally, non-significant variation in rod chromophore proportions was observed between individuals, with some species exhibiting a similar proportion across individuals, while other species exhibit a larger range (Table S7).…”

Section: Discussionmentioning

confidence: 99%

Visual pigment evolution in Characiformes: the dynamic interplay of teleost whole-genome duplication, surviving opsins and spectral tuning

Escobar‐Camacho

Carleton

Narain

et al. 2019

Preprint

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33Vision represents an excellent model for studying adaptation, given the genotype-to-34 phenotype-map that has been characterized in a number of taxa. Fish possess a diverse 35 range of visual sensitivities and adaptations to underwater light making them an 36 excellent group to study visual system evolution. In particular, some speciose but 37 understudied lineages can provide a unique opportunity to better understand aspects of 38 visual system evolution such as opsin gene duplication and neofunctionalization. In this 39 study, we characterized the visual system of Neotropical Characiformes, which is the 40 result of several spectral tuning mechanisms acting in concert including gene 41 duplications and losses, gene conversion, opsin amino acid sequence and expression 42 variation, and A 1 /A 2 -chromophore shifts. The Characiforms we studied utilize three cone 43 opsin classes (SWS2, RH2, LWS) and a rod opsin (RH1). However, the characiform's 44 entire opsin gene repertoire is a product of dynamic evolution by opsin gene loss 45 (SWS1, RH2) and duplication (LWS, RH1). The LWS-and RH1-duplicates originated 46 from a teleost specific whole-genome duplication as well as characiform-specific 47 duplication events. Both LWS-opsins exhibit gene conversion and, through substitutions 48 in key tuning sites, one of the LWS-paralogs has acquired spectral sensitivity to green 49 light. These sequence changes suggest reversion and parallel evolution of key tuning 50 sites. In addition, characiforms exhibited species-specific differences in opsin 51 expression. Finally, we found interspecific and intraspecific variation in the use of A 1 /A 2 -52 chromophores correlating with the light environment. These multiple mechanisms may 53 be a result of the highly diverse visual environments where Characiformes have evolved. 54 55 58 relates to the environment. Evolutionary studies of genes such as the ones involved in 59 the first steps of vision can provide valuable insights in the acquisition of new functions 60 and their adaptive significance. In vertebrates, vision starts when light reaches the retina61 and is detected by rod (night vision) or cone (diurnal vision) photoreceptors.62 Photoreceptors are packed with visual pigments that are composed of two components: 63 an opsin protein with seven α-helices enclosing a ligand-binding pocket, and a light-64 sensitive chromophore, 11-cis retinal (Bowmaker 2008; Yokoyama 2008). There can be 65 3 multiple cone types containing different visual pigments that absorb light maximally in 66 different parts of the wavelength spectrum. 67 68 There are four classes of cone pigments encoded by opsin genes among vertebrates: a 69 short-wave class (SWS1) sensitive to ultraviolet-violet light (350-400 nm), a second 70 short-wave class (SWS2) sensitive to violet-blue (410-490 nm), a middle-wave class 71 (RH2) sensitive to green (480-535 nm), and a middle-to long-wave class (LWS) 72 sensitive to the green and red spectral region (490-570 nm) (Bowmaker and Hunt 2006; 73 Bowmaker 2008). All four ...

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“…In Lake Malawi alone, there are over 500 species of cichlids, inhabiting a diversity of environmental and feeding niches. Cichlid species exhibit a high degree of habitat fidelity and partition their environment along discrete ecological axes, including distinct biotic (food availability, predation, and parasites) and abiotic (light, water chemistry) environments that play a critical role in the origins and maintenance of cichlid biodiversity [12][13][14][15][16][17]. Predation on Malawi cichlids is considered to be relatively low, which is thought to have contributed to their evolutionary and ecological success [18].…”

Section: Introductionmentioning

confidence: 99%

Diversity in rest-activity patterns among Lake Malawi cichlid fishes suggests novel axis of habitat partitioning

Lloyd

Chhouk

Keene

et al. 2020

Preprint

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Animals display remarkable diversity in rest and activity patterns that are regulated by endogenous foraging strategies, social behaviors, and predator avoidance. Alteration in the circadian timing of activity or the duration of rest-wake cycles provide a central mechanism for animals to exploit novel niches. The diversity of the 3000 cichlid species throughout the world provides a unique opportunity to examine variation in locomotor activity and rest. Lake Malawi alone is home to over 500 species of cichlids that display divergent behaviors and inhabit well-defined niches throughout the lake. These species are presumed to be diurnal, though this has never been tested systematically. Here, we measure locomotor activity across the circadian cycle in 12 cichlid species from divergent lineages and distinct habitats. We document surprising variability in the circadian time of locomotor activity and the duration of rest. In particular, we identify a single species, Tropheops sp. red cheek that is nocturnal. Nocturnal behavior was maintained when fish were provided shelter, but not under constant darkness, suggesting it results from acute response to light rather than an endogenous circadian rhythm. Finally, we show that nocturnality is associated with increased eye size, suggesting a link between visual processing and nighttime activity. Together, these findings identify diversity of locomotor behavior in Lake Malawi cichlids and provide a system for investigating the molecular and neural basis underlying the evolution of nocturnal activity.

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Visual adaptation in Lake Victoria cichlid fishes: depth-related variation of color and scotopic opsins in species from sand/mud bottoms

Cited by 31 publications

References 45 publications

Cardinalfishes (Apogonidae) show visual system adaptations typical of nocturnally and diurnally active fish

Cardinalfishes (Apogonidae) show visual system adaptations typical of nocturnally and diurnally active fish

Visual pigment evolution in Characiformes: the dynamic interplay of teleost whole-genome duplication, surviving opsins and spectral tuning

Diversity in rest-activity patterns among Lake Malawi cichlid fishes suggests novel axis of habitat partitioning

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