Enhanced short-wavelength sensitivity in the blue-tongued skink, <i>Tiliqua rugosa</i>

Nagloo, Nicolas; Mountford, Jessica Kate; Gundry, Ben J; Hart, Nathan S.; Collin, Shaun P.; Hemmi, Jan M.

doi:10.1101/2022.03.25.485754

Cited by 2 publications

(1 citation statement)

References 74 publications

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“…This means many known tuning sites on these opsins are not represented in this data (7 for RH1, 2 for RH2, 4 for SWS2 were recovered), and thus the potential variance within cannot be examined. Therefore we must estimate that the sensitivity of the opsins of Lerista and Ctenotus are similar to previously described skink species (Tiliqua rugosa) and are as follows: LWS ≈ 560nm; RH1 ≈ 491nm; RH2 ≈ 495nm; SWS1 ≈ 360nm and SWS2 ≈ 440nm (Nagloo et al, 2016). Further evidence that these regions are conserved in Lerista and Ctenotus comes from the recently released genome of Lerista edwardsae (accession number GCA_029204185.1), where the full SWS2 and RH2 genes can be recovered.…”

Section: Targeted Capture Of Skink Opsinsmentioning

confidence: 80%

Retention of the full visual opsin repertoire in Australia’s cryptozoic lizards

Ford,

Ludington,

Bradford

et al. 2024

Preprint

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Australian scincid lizards in the sister-generaLeristaandCtenotusare a prominent system for understanding adaptation in the transition from surface to fossorial life. The approximately 205 species in this group exhibit extreme diversity in morphology and ecology.LeristaandCtenotusboth include diurnal and surface-active species that are fully pentadactyl, andLeristaalso contains many specialised limb-reduced and limbless sand-swimmers. To understand how the visual systems of these lizards have responded to their varied photic environments, we examined the five opsin genes encoding the pigments that mediate colour and dim-light vision. These genes were sequenced for 59 species ofLeristaandCtenotusand analysed for variation in selection pressures among amino acid sites and across branches in the species tree. All five opsins are present and intact in all species ofLeristaandCtenotusexamined, and we identified signals of positively selected substitutions in all five opsin genes –RH1, which mediates scotopic vision, and four cone opsins associated with photopic vision (SWS1, SWS2, RH2, LWS). Most comparisons of selection pressures did not show significant differences according to broad ecological divisions. Only LWS showed a signal of relaxed selection in sand-swimming (limb reduced) versus less fossorial (fully limbed)Lerista. These results suggest that photopic abilities are retained across both clades, even in the most fossorial species, highlighting a need for studies of visual ecology of Australian skinks, and prompts caution with regards to generalisations about degenerate vision in fossorial squamates.

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Section: Targeted Capture Of Skink Opsinsmentioning

confidence: 80%

Retention of the full visual opsin repertoire in Australia’s cryptozoic lizards

Ford,

Ludington,

Bradford

et al. 2024

Preprint

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Lizard visual ecology

Fleishman

2024

Front. Amphib. Reptile Sci.

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Visual ecology is the study of how visual systems are evolutionarily adapted to the light conditions animals experience and the visual tasks they must perform. The greatest progress in this field has been made in studies of aquatic systems. Our understanding of the influence of how different terrestrial habitats have shaped the evolution of visual physiology and anatomy is more limited. Lizards are an excellent model system for examining terrestrial visual ecology because in most cases, each species experiences a limited range of habitat light conditions and these differ among species. Some aspects of visual physiology and anatomy have evolved in response to habitat conditions, while others are widely shared by a great diversity of species, suggesting that their features are largely inherited and have changed very little through evolutionary time. Understanding which features have evolved as specializations to current conditions and which are inherited and largely unchanged is critical to understanding the role that visual ecology plays in shaping behavior. In this article I review some basic features of the lizard visual system, including the processes by which lizards estimate distance and depth. I then explore the evolutionary response (or lack thereof) to differences in habitat structure, light intensity and spectral quality. I also explore some relationships between lizard color patterns and their color perception. The phylogenetic range of species that have been studied is small, and many key aspects of behavior have received relatively little attention. These are potentially rich areas for future study.

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Enhanced short-wavelength sensitivity in the blue-tongued skink, Tiliqua rugosa

Cited by 2 publications

References 74 publications

Retention of the full visual opsin repertoire in Australia’s cryptozoic lizards

Retention of the full visual opsin repertoire in Australia’s cryptozoic lizards

Lizard visual ecology

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