Vision using multiple distinct rod opsins in deep-sea fishes

Musilová, Zuzana; Cortesi, Fabio; Matschiner, Michael; Stieb, Sara M.; Busserolles, Fanny de; Malmstroem, Martin; Toerresen, Ole K; Mountford, Jessica Kate; Hanel, Reinhold; Jakobsen, Kjetill S.; Carleton, Karen L.; Jentoft, Sissel; Marshall, Justin; Salzburger, Walter

doi:10.1101/424895

Cited by 54 publications

(199 citation statements)

References 39 publications

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“…However, since fossils do not directly constrain maximum ages, the upper boundary of 55 Ma was arbitrarily specified by Jacobsen et al (2014), and the divergence times estimated in their study would likely be underestimated if Anguillidae in fact originated earlier than 55 Ma. Nevertheless, we consider the timeline proposed by Jacobsen et al (2014) plausible for the following reasons: (i) According to this timeline, European and American anguillid species (A. anguilla and A. rostrata) diverged from Indo-Pacific members of the genus around 10.8 Ma, which is consistent with the Messinian age (7.2-5.3 Ma) of the earliest fossils of the genus, known from the Gessoso Solififera Formation in Northern Italy (Dela Pierre et al 2011); (ii) the timeline is consistent with those of two other recent studies based on genome-wide data (Musilova et al 2019) and a massive taxon set (Rabosky et al 2018), as the most recent common ancestor of A. anguilla and A. japonica (the only species pair included in all three studies) was estimated at 13.8 Ma in Jacobsen et al (2014), at 12.4 Ma in Musilova et al (2019), and at 12.9 Ma in Rabosky et al (2018).…”

Section: Supplementary Notessupporting

confidence: 90%

“…Additionally, we compiled a multi-locus phylogenetic dataset based on genome assemblies of the five species A. anguilla, A. japonica, A. marmorata, A. obscura, and A. megastoma to estimate divergence times among Anguilla species independently of the timeline of Jacobsen et al (2014). Of these five species, genome assemblies of A. anguilla (NCBI accession GCA 000695075; Henkel et al 2012a) and A. japonica (NCBI accession GCA 000470695; Henkel et al 2012b) were included in the large-scale phylogenomic analysis of Musilova et al (2019), in which their divergence was estimated at around 12.37 Ma. We thus extracted ortholog sequences, corresponding to the loci used in Musilova et al (2019), from the three new genome assemblies of A. marmorata, A. obscura, and A. megastoma ( Supplementary Table 5), and aligned these jointly with those of A. anguilla and A. japonica.…”

Section: Supplementary Notesmentioning

confidence: 99%

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Stable species boundaries despite ten million years of hybridization in tropical eels

Barth

Gubili²,

Matschiner

et al. 2020

Nat Commun

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Genomic evidence is increasingly underpinning that hybridization between taxa is commonplace, challenging our views on the mechanisms that maintain their boundaries. Here, we focus on seven catadromous eel species (genus Anguilla) and use genome-wide sequence data from more than 450 individuals sampled across the tropical Indo-Pacific, morphological information, and three newly assembled draft genomes to compare contemporary patterns of hybridization with signatures of past introgression across a time-calibrated phylogeny. We show that the seven species have remained distinct for up to 10 million years and find that the current frequencies of hybridization across species pairs contrast with genomic signatures of past introgression. Based on near-complete asymmetry in the directionality of hybridization and decreasing frequencies of later-generation hybrids, we suggest cytonuclear incompatibilities, hybrid breakdown, and purifying selection as mechanisms that can support species cohesion even when hybridization has been pervasive throughout the evolutionary history of clades.

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Section: Supplementary Notessupporting

confidence: 90%

Section: Supplementary Notesmentioning

confidence: 99%

Stable species boundaries despite ten million years of hybridization in tropical eels

Barth

Gubili²,

Matschiner

et al. 2020

Nat Commun

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“…As previously mentioned, modelling predicts long-wavelength sensitive photoreceptors in reef fishes (Lythgoe, 1979;Marshall et al, 2003b). The recent rise of next-generation sequencing technologies has made it possible to survey the visual systems of a much larger number of reef fishes in a lot more detail than before (e.g., Cortesi et al 2015a,b;Musilova et al, 2018) It is important to realize that a snapshot of the genes does not necessarily tell us the time at which the genes are active, either in evolutionary or lifetime timescales. Extensive work on cichlids (Cichlidae) and other freshwater fishes suggests that for some species at least, the genomic opsin repertoire can be used in a pick-and mix way, allowing the animal the best combination possible for the environment in which it finds itself (Carleton et al, 2005;Bowmaker & Loew, 2007;Bowmaker, 2008).…”

Section: Colour Vision Futurementioning

confidence: 99%

“…These range from extant species with a single remaining opsin gene to species with up to 40 opsin gene copies in their genomes (Cortesi et al, 2015;Hofmann and Carleton, 2009;Musilova et al, 2018).…”

Section: Colour Vision Futurementioning

confidence: 99%

“…Musilova and colleagues compared the gene expression in 36 representative species distributed across teleost phylogeny, including reef fishes, and found that, consistent with anatomical measurements and predictive models of colour vision, many species express up to four cone opsin genes within their retina. However, they also found a considerable number of species that had more than four cone opsin transcripts at what appeared to be functionally relevant levels, within their retina(Musilova et al, 2018). Since two, three or at most four differently tuned photoreceptors suffice to solve colour related tasks under water, the question of why fishes have, and also express, so many different opsin genes in the first place remains interesting.…”

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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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Origin and adaptation of green‐sensitive (RH2) pigments in vertebrates

Yokoyama

Jia

2020

FEBS Open Bio

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One of the critical times for the survival of animals is twilight where the most abundant visible lights are between 400 and 550 nanometres (nm). Green‐sensitive RH2 pigments help nonmammalian vertebrate species to better discriminate wavelengths in this blue‐green region. Here, evaluation of the wavelengths of maximal absorption (λmaxs) of genetically engineered RH2 pigments representing 13 critical stages of vertebrate evolution revealed that the RH2 pigment of the most recent common ancestor of vertebrates had a λmax of 503 nm, while the 12 ancestral pigments exhibited an expanded range in λmaxs between 474 and 524 nm, and present‐day RH2 pigments have further expanded the range to ~ 450–530 nm. During vertebrate evolution, eight out of the 16 significant λmax shifts (or |Δλmax| ≥ 10 nm) of RH2 pigments identified were fully explained by the repeated mutations E122Q (twice), Q122E (thrice) and M207L (twice), and A292S (once). Our data indicated that the highly variable λmaxs of teleost RH2 pigments arose from gene duplications followed by accelerated amino acid substitution.

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Vision using multiple distinct rod opsins in deep-sea fishes

Cited by 54 publications

References 39 publications

Stable species boundaries despite ten million years of hybridization in tropical eels

Stable species boundaries despite ten million years of hybridization in tropical eels

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

Origin and adaptation of green‐sensitive (RH2) pigments in vertebrates

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