Bertolesi GE , Debnath N , Malik HR , Man LLH , McFarlane S .

             response to light stimulus

	Figure 1. Pigmentation response induced by reflected light from the substrate (background adaptation) or environmental light (dark/light) over Xenopus laevis development. (A) Pigmentation levels at different developmental times represented approximately (50%; day 5/6) from embryos raised on a white background (WB) (yellow column). The light shines from above in cycles of 12 h ON/12 h OFF and the pigmentation is measured at the middle of the light cycle. The timeline in days (X-axis) of embryos maintained at 16°C until stage 43/44 is assigned to the approximate developmental stage. Tadpoles raised on a white substrate (WB) are switched either to a black background for 4 h (BB; red columns) or dark for 30 min (D; green columns) (see schematic). The pigmentation response is measured in the dorsal head (see pictures). (B) Pigmentation response of stage 43/44 embryos compared to enucleation (No eye), pinealectomy (No P.C) or both (No eye, No P.C.). The surgery is performed 24 h before pigmentation measurement. (C) Morphological pigmentation of embryos induced by raising tadpoles on a black background from early stages. Note the difference in the “morphological” pigmentation (increase in melanophore number mainly around the eye) when tadpoles are raised on a BB vs. the quick “physiological” responses seen in tadpoles raised on a WB. See text for additional details.
	Figure 2. Expression of opsins in the Xenopus larval eye, pineal complex, and skin. (A) RT-PCR analysis showing mRNA expression of the indicated opsins at stage 43/44 in the whole embryo and isolated tails, and in a melanophore cell line (MEX) obtained from stage 30–35 X. laevis tadpoles (Kashina et al., 2004). RT-PCR conditions are similar to those published previously (Bertolesi et al., 2020, 2021). (B) Opsins identified in the X. laevis genome and their expression in the pineal complex, eye and tails. The putative amino acid sequences were compared, and a molecular phylogenetic analysis performed by the maximum-likelihood method is shown (not to scale). Type II opsins are grouped according to what was initially considered as their tissue localization: visual opsins (red); pineal opsins (green); non-visual opsins (blue); neuropsins (orange); photoisomerases (pink) and melanopsins (purple). Groups are also approximately reflected in the phylogenetic tree. Brackets denote genes duplicated and maintained on the long (L) and short (S) chromosomes, with single copy genes indicated with an asterisk. The table show the summary of expression of opsins in the eye (Bertolesi et al., 2021), the pineal complex (Bertolesi et al., 2020), and the tails and MEX cells as determined by RT-PCR as in A. (C) A comparative expression analysis determined by RNAseq of opn4 in different organs from both genes (L and S) is reproduced from Xenbase (http://www.xenbase.org/, RRID:SCR_003280). Darker color reflects higher mRNA expression.
	Figure 3. Localization and developmental expression of opsins in the eye. (A) Schematic of the central retina showing the expression of opsins in photoreceptors in the outer nuclear layer (ONL) in rods (Rh1; green and Sws2; white) and cones (Lws; orange and Sws1, blue). Pinopsin (light blue) is always co-expressed dorsally with a few sws1 positive cells. Melanopsin (yellow) is expressed both by intrinsically photosensitive horizontal cells (ipHC) located dorsally in the retina in the inner nuclear layer (INL), and a minor population of retinal ganglion cells in the ganglion cell layer (GCL) (RGCs; 2% of total), called the intrinsically photosensitive RGCs (ipRGC). opn5 mRNA (magenta) is expressed by cells in the outer portion of the INL and in the GCL, while opn8 mRNA (pink) is present in cells in the inner part of the INL, likely amacrine cells. opn6 (purple) expressing cells sit at the boundary of the proliferative CMZ and the ONL. rgr and rrh mRNAs (pink) are expressed by the RPE but excluded from the CMZ. A developmental timeline is schematized with an arrow at the bottom, with the emergence of opsin expression or specific behavioral responses indicated. (B) Opsins expressed in the eye, the pineal complex, and the skin (tails or MEX cells) of Xenopus laevis are shown at the approximate absorbance peak of their spectral sensitivity, and compared to the spectral sensitivity of human visual opsins. See text for additional details.

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