The evolution of red color vision is linked to coordinated rhodopsin tuning in lycaenid butterflies

Color vision has evolved multiple times in both vertebrates and invertebrates and is largely determined by the number and variation in spectral sensitivities of distinct opsin subclasses. However, because of the difficulty of expressing long-wavelength (LW) invertebrate opsins in vitro, our understanding of the molecular basis of functional shifts in opsin spectral sensitivities has been biased toward research primarily in vertebrates. This has restricted our ability to address whether invertebrate G_q protein-coupled opsins function in a novel or convergent way compared to vertebrate G_t opsins. Here we develop a robust heterologous expression system to purify invertebrate rhodopsins, identify specific amino acid changes responsible for adaptive spectral tuning, and pinpoint how molecular variation in invertebrate opsins underlie wavelength sensitivity shifts that enhance visual perception. By combining functional and optophysiological approaches, we disentangle the relative contributions of lateral filtering pigments from red-shifted LW and blue short-wavelength opsins expressed in distinct photoreceptor cells of individual ommatidia. We use in situ hybridization to visualize six ommatidial classes in the compound eye of a lycaenid butterfly with a four-opsin visual system. We show experimentally that certain key tuning residues underlying green spectral shifts in blue opsin paralogs have evolved repeatedly among short-wavelength opsin lineages. Taken together, our results demonstrate the interplay between regulatory and adaptive evolution at multiple G_q opsin loci, as well as how coordinated spectral shifts in LW and blue opsins can act together to enhance insect spectral sensitivity at blue and red wavelengths for visual performance adaptation.

Opsins belong to a diverse multigene family of G protein-coupled receptors that bind to a small nonprotein retinal moiety to form photosensitive rhodopsins and enable vision across animals (1–4). The tight relationship between opsin genotypes and spectral sensitivity phenotypes offers an ideal framework to analyze how specific molecular changes give rise to adaptations in visual behaviors (5). Notably, independent opsin gene gains and losses (6–13), genetic variation across opsins (14–16), spectral tuning mutations within opsins (17–21), and alterations in visual regulatory networks (22, 23) have contributed to opsin adaptation. Yet, the molecular and structural changes underlying the remarkable diversification of spectral sensitivity phenotypes identified in some invertebrates, including crustaceans and insects (24–27), are far less understood than those in vertebrate lineages (28–32).The diversity of opsin-based photoreceptors observed across animal visual systems is produced by distinct ciliary vertebrate c-opsin and invertebrate rhabdomeric based r-opsin subfamilies that mediate separate phototransduction cascades (31, 33–35). Vertebrate c-opsins function through the G protein transducing (G_t) signaling pathway, which activates cyclic nucleotide phosphodiesterase, ultimately resulting in a hyperpolarization response in photoreceptor cells through the opening of selective K⁺ channels (31, 36). By contrast, insect opsins transmit light stimuli through a G_q-type G protein (33, 37) with phosphoinositol (PLCβ) acting as an effector enzyme to achieve TRP channel depolarization in the invertebrate photoreceptor cell (34, 38).All vertebrate visual cone opsins derive from four gene families: short-wavelength-sensitive opsins SWS1 (or ultraviolet UV]) with λ_max 344 to 445 nm and SWS2 with λ_max 400 to 470 nm, and longer-wavelength-sensitive opsins that specify the green MWS (or Rh2) pigments with λ_max 480 to 530 nm and red-sensitive LWS pigments with λ_max 500 to 570 nm (5, 30). Most birds and fish have retained the four ancestral opsin genes (39), with notable opsin expansions in cichlid fish opsins (23, 40), whereas SWS1 is extinct in monotremes, and SWS2 and M opsins are lost in marsupials and eutherian mammals (41). In primates, trichromatic vision is conferred through SWS1 (λ_max = 414 nm) and recent duplicate MWS (λ_max = 530 nm) and LWS opsins (λ_max = 560 nm) (42–44). In vertebrates, molecular evolutionary approaches and well-established in vitro opsin purification have identified the complex interplay between opsin duplications, regulatory and protein-coding mutations controlling opsin gene tuning, and spectral phenotypes notably in birds, fish, and mammals (45–47).Insect opsins are phylogenetically distinct but functionally analogous to those of vertebrates, and the ancestral opsin repertoire consists of three types of light-absorbing rhabdomeric G_q-type opsin specifying UV (350 nm), short-wavelength (blue, 440 nm) and long-wavelength pigments (LW, 530 nm) (48). Given the importance of color-guided behaviors and the remarkable photoreceptor spectral diversity observed in insects (26, 27), the dynamic opsin gene diversification found across lineages (Fig. 1) highlights their potentially central role in adaptation (27, 49, 50), yet the molecular basis of opsin functionality of rhabdomeric invertebrate G_q opsins remains understudied.Open in a separate windowFig. 1.Visual opsin gene evolution and spectral tuning mechanisms in insects. Visual opsin genes of the Atala hairstreak (E. atala, Lepidoptera, Lycaenidae) in comparison with those encoded in the genomes of diverse insects. The opsin types are highlighted in gray for UV, in blue for short wavelength (SW), and in green for long wavelength (LW). Numbers indicate multiple opsins, whereas no dot indicates gene loss. Colored circles indicate instances of shifted spectral sensitivities in at least one of the encoded opsins. The direction of shift is inferred from the opsin lambda max that departs from the typical range of absorbance in the opsin subfamily using wavelength boundaries for the various colors: UV <380 nm, violet 380 to 435 nm, blue 435 to 492 nm, green 492 to 530 nm, and red shifted >530 nm. Coleopteran lineages, and some hemipterans, lost the blue opsin locus and compensated for the loss of blue sensitivity via UV and/or LW gene duplications across lineages (11, 12). In butterflies, extended photosensitivity at short wavelengths is observed in Heliconius erato with two UV opsins at λ_max = 355 nm and 398 nm (10) and in P. rapae with two blue opsins with λ_max = 420 and 450 nm (17). A blue opsin duplication occurred independently in lycaenid butterflies (61). LW opsin duplications occurred independently in most major insect lineages (6, 16, 55) and confer a variable range of LW sensitivities with or without additional contributions from lateral filtering. In order to extend spectral sensitivity at longer wavelengths while sharpening blue acuity, some lycaenid butterflies have evolved a new color vision mechanism combining spectral shifts at a duplicate blue opsin and at the LW opsin. Images credit: Christopher Adams (illustrator).The recurrent evolution of red receptors in insects in particular suggests that perception of longer wavelengths can play an important role in the context of foraging, oviposition, and/or conspecific recognition (6, 27, 51–54). In butterflies, several mechanisms are likely to have provided extended spectral sensitivity to longer wavelengths. LW opsin duplications along with the evolution of lateral filtering between ommatidia has been demonstrated in two papilionids, Papilio xuthus (27) and Graphium sarpedon (55), as well as in a riodinid (Apodemia mormo) (6, 54). Lateral filtering pigments are relatively widespread across butterfly lineages, e.g., Heliconius (56), Pieris (57), Colias erate (58), and some moths Adoxophyes orana (59) and Paysandisia archon (60)]. These pigments absorb short wavelengths and aid in shifting the sensitivity peak of green LW photoreceptors to longer wavelengths (27, 51, 56, 57, 61, 62). Despite creating distinct spectral types that can contribute to color vision, as identified in nymphalid (56), pierid (57), and lycaenid (62) species, all of which lack duplicated LW opsins (61, 63), lateral filtering alone cannot extend photoreceptor sensitivity toward the far red (700 to 750 nm) beyond the exponentially decaying long-wavelength rhodopsin absorbance spectrum (51). Thus, molecular variation of ancestral LW opsin genes is likely to have contributed an as yet underexplored mechanism to the diversification of long-wavelength photoreceptor spectral sensitivity. However, disentangling the relative contributions of lateral filtering and pure LW opsin properties has remained technically challenging using classical electrophysiological approaches (14, 64, although see, e.g., refs. 65, 66, 67) and has been limited by the lack of in vitro expression systems suitable for LW opsins.While opsin duplicates have been identified in numerous organisms, the spectral tuning mechanisms and interplay between new opsin photoreceptors in invertebrate visual system evolution are less well understood. Here we combine physiological, molecular, and heterologous approaches to start closing this gap in our knowledge of invertebrate G_q opsin evolution by investigating the functions, spectral tuning, and implications of evolving new combinations of short- and long-wavelength opsin types in lycaenid species. This butterfly group, comprising the famous blues, coppers, and hairstreaks, is the second largest family with about 5,200 (28%) of the some 18,770 described butterfly species (68). In light of their remarkable behavioral, ecological, and morphological diversity (69, 70), as well as pioneer studies in the Lycaena and Polyommatus genera supporting the rapid evolution of color vision in certain lineages (56, 61, 62), lycaenids provide an ideal candidate system for investigating opsin evolution and visual adaptations. Using the Atala hairstreak, Eumaeus atala, as a molecular and ecological model, we find coordinated spectral shifts at short- and long-wavelength G_q opsin loci and demonstrate that the combination of six ommatidial classes of photoreceptors in the compound eye uniquely extend spectral sensitivity at long wavelengths toward the far-red while concurrently sharpening acuity of multiple blue wavelengths. Together, these findings link the evolution of four-opsin visual systems to adaptation in the context of finely tuned color perception critical to the behavior of these butterflies.