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. 2021 Oct;24(10):2207-2218.
doi: 10.1111/ele.13850. Epub 2021 Aug 4.

Environmental gradients predict the ratio of environmentally acquired carotenoids to self-synthesised pteridine pigments

Devi Stuart-Fox  1 Katrina J Rankin  1 Adrian Lutz  2 Adam Elliott  1 Andrew F Hugall  3 Claire A McLean  1   3 Iliana Medina  1
Affiliations

Environmental gradients predict the ratio of environmentally acquired carotenoids to self-synthesised pteridine pigments

Devi Stuart-Fox et al. Ecol Lett. 2021 Oct.

Abstract

Carotenoids are important pigments producing integument colouration; however, their dietary availability may be limited in some environments. Many species produce yellow to red hues using a combination of carotenoids and self-synthesised pteridine pigments. A compelling hypothesis is that pteridines replace carotenoids in environments where carotenoid availability is limited. To test this hypothesis, we quantified concentrations of five carotenoid and six pteridine pigments in multiple skin colours and individuals from 27 species of agamid lizards. We show that environmental gradients predict the ratio of carotenoids to pteridines; carotenoid concentrations are lower and pteridine concentrations higher in arid environments with low vegetation productivity. Both carotenoid and pteridine pigments were present in all species, but only pteridine concentrations explained colour variation among species and there were no correlations between carotenoid and pteridine pigments with a similar hue. These results suggest that in arid environments, where carotenoids are likely limited, species may compensate by synthesising more pteridines but do not necessarily replace carotenoids with pteridines of similar hue.

Keywords: animal colouration; comparative analysis; habitat productivity; liquid chromatography-mass spectrometry; signalling.

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