Dimerization of visual pigments in vivo

Significance Despite in vitro evidence, it remains unclear whether the rod visual pigment rhodopsin exists as dimers in vivo. With a unique mouse line that expresses the blue cone opsin transgenically in rods, we showed that, in the absence of chromophore, the transgenic cone opsin can mature and target to the outer segment if and only if rhodopsin is present to help it along (i.e., forming heterodimers in the endoplasmic reticulum). Furthermore, we have confirmed a key interaction domain for rhodopsin dimerization and show that, again in vivo, rhodopsin maturation and targeting to the outer segment becomes defective when dimerization is disrupted. This work provides in vivo evidence for rhodopsin existing as a dimer. It is a deeply engrained notion that the visual pigment rhodopsin signals light as a monomer, even though many G protein-coupled receptors are now known to exist and function as dimers. Nonetheless, recent studies (albeit all in vitro) have suggested that rhodopsin and its chromophore-free apoprotein, R-opsin, may indeed exist as a homodimer in rod disk membranes. Given the overwhelmingly strong historical context, the crucial remaining question, therefore, is whether pigment dimerization truly exists naturally and what function this dimerization may serve. We addressed this question in vivo with a unique mouse line (S-opsin+Lrat−/−) expressing, transgenically, short-wavelength–sensitive cone opsin (S-opsin) in rods and also lacking chromophore to exploit the fact that cone opsins, but not R-opsin, require chromophore for proper folding and trafficking to the photoreceptor’s outer segment. In R-opsin’s absence, S-opsin in these transgenic rods without chromophore was mislocalized; in R-opsin’s presence, however, S-opsin trafficked normally to the rod outer segment and produced functional S-pigment upon subsequent chromophore restoration. Introducing a competing R-opsin transmembrane helix H1 or helix H8 peptide, but not helix H4 or helix H5 peptide, into these transgenic rods caused mislocalization of R-opsin and S-opsin to the perinuclear endoplasmic reticulum. Importantly, a similar peptide-competition effect was observed even in WT rods. Our work provides convincing evidence for visual pigment dimerization in vivo under physiological conditions and for its role in pigment maturation and targeting. Our work raises new questions regarding a potential mechanistic role of dimerization in rhodopsin signaling.

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