Molecular Mechanism of Light-Induced Conformational Switching of the LOV Domain in Aureochrome-1.

Light oxygen voltage-sensing (LOV) domains are widely found in photoreceptor proteins of plants, algae, fungi, and bacteria. Structural studies of LOV domains suggest that Phe and Gln residues located in the proximity of the chromophore undergo conformational changes upon illumination; however, the molecular mechanism associated with activation of the effector domain remains to be elucidated. Photozipper (PZ) protein is an N-terminally truncated aureochrome-1 comprising a LOV domain and a basic leucine zipper domain. Blue light (BL) induces PZ dimerization and subsequently increases its affinity for target DNA. In this study, we prepared PZ mutants with substitutions of F298 and Q317 and performed quantitative analyses in dark and light states. Substitutions of Q317 significantly reduced the light-induced changes in PZ affinity for the target DNA, especially in the case of the high affinities observed in the dark state. Upon illumination, all PZ mutants showed increased affinity for the target sequence, which demonstrated a clear correlation with the dimer fraction of each PZ mutant. These results suggest the existence of a conformational equilibrium and that its shift by a synergistic interaction between the chromophore and protein moiety probably enables BL-regulated switching of aureochrome-1.

Adaptation of cone pigments found in green rods for scotopic vision through a single amino acid mutation.

Most vertebrate retinas contain a single type of rod for scotopic vision and multiple types of cones for photopic and color vision. The retinas of certain amphibian species uniquely contain two types of rods: red rods, which express rhodopsin, and green rods, which express a blue-sensitive cone pigment (M1/SWS2 group). Spontaneous activation of rhodopsin induced by thermal isomerization of the retinal chromophore has been suggested to contribute to the rod's background noise, which limits the visual threshold for scotopic vision. Therefore, rhodopsin must exhibit low thermal isomerization rate compared with cone visual pigments to adapt to scotopic condition. In this study, we determined whether amphibian blue-sensitive cone pigments in green rods exhibit low thermal isomerization rates to act as rhodopsin-like pigments for scotopic vision. Anura blue-sensitive cone pigments exhibit low thermal isomerization rates similar to rhodopsin, whereas Urodela pigments exhibit high rates like other vertebrate cone pigments present in cones. Furthermore, by mutational analysis, we identified a key amino acid residue, Thr47, that is responsible for the low thermal isomerization rates of Anura blue-sensitive cone pigments. These results strongly suggest that, through this mutation, anurans acquired special blue-sensitive cone pigments in their green rods, which could form the molecular basis for scotopic color vision with normal red rods containing green-sensitive rhodopsin.

Target Sequence Recognition by a Light-Activatable Basic Leucine Zipper Factor, Photozipper.

Photozipper (PZ) is a light-activatable basic leucine zipper (bZIP) protein composed of a bZIP domain and a light-oxygen-voltage-sensing domain of aureochrome-1. Blue light induces dimerization and subsequently increases the affinity of PZ for the target DNA sequence. We prepared site-directed PZ mutants in which Asn131 (N131) in the basic region was substituted with Ala and Gln. N131 mutants showed spectroscopic and dimerization properties almost identical to those of wild-type PZ and an increase in helical content in the presence of the target sequence. Quantitative analyses by an electrophoretic mobility shift assay and quartz crystal microbalance (QCM) measurements demonstrated that the half-maximal effective concentrations of N131 mutants to bind to the target sequence were significantly higher than those of PZ. QCM data also revealed that N131 substitutions accelerated the dissociation without affecting the association, suggesting that a base-specific interaction of N131 occurred after the association between PZ and DNA. Activation of PZ by illumination decreased both the standard errors and the unstable period of QCM data. Optical control of transcription factors will provide new knowledge of the recognition of the target sequence.

Dimeric Structure of the Blue Light Sensor Protein Photozipper in the Active State.

The light oxygen voltage-sensing (LOV) domain plays a crucial role in blue light (BL) sensing in plants and microorganisms. LOV domains are usually associated with the effector domains and regulate the activities of effector domains in a BL-dependent manner. Photozipper (PZ) is monomeric in the dark state. BL induces reversible dimerization of PZ and subsequently increases its affinity for the target DNA sequence. In this study, we report the analyses of PZ by pulsed electron-electron double resonance (PELDOR). The neutral flavin radical was formed by BL illumination in the presence of dithiothreitol in the LOV-C254S (without the bZIP domain) and PZ-C254S mutants, where the cysteine residue responsible for adduct formation was replaced with serine. The magnetic dipole interactions of 3 MHz between the neutral radicals were detected in both LOV-C254S and PZ-C254S, indicating that these mutants are dimeric in the radical state. The PELDOR simulation showed that the distance between the radical pair is close to that estimated from the dimeric crystal structure in the "light state" [Heintz, U., and Schlichting, I. (2016) eLife 5, e11860], suggesting that in the radical state, LOV domains in PZ-C254S form a dimer similar to that of LOV-C254S, which lacks the bZIP domain.

Molecular Mechanism of Photozipper, a Light-Regulated Dimerizing Module Consisting of the bZIP and LOV Domains of Aureochrome-1.

Aureochrome-1 (AUREO1) is a blue light (BL) receptor responsible for the BL-induced blanching of a stramenopile alga, Vaucheria frigida. The AUREO1 protein contains a central basic region/leucine zipper (bZIP) domain, and a C-terminal light-oxygen-voltage-sensing (LOV) domain. BL induces the dimerization of monomeric AUREO1, which subsequently increases the affinity of this transcription factor for its target DNA [Hisatomi, O., et al. (2014) J. Biol. Chem. 289, 17379-17391]. We constructed a synthetic gene encoding N-terminally truncated monomeric AUREO1 (designated Photozipper) to elucidate the molecular mechanism of this BL-regulated transcription factor and to develop it as an optogenetic tool. In this study, four different Photozipper (PZ) protein constructs were prepared comprising different N-terminal truncations. The monomer-dimer equilibria of the PZ constructs were investigated in the dark and light states. Dynamic light scattering and size-exclusion chromatography analyses revealed that the apparent dissociation constants of PZ dimers with and without the ZIP region were ~100 and 30 µM, respectively, indicating that the ZIP region stabilized the monomeric form in the dark state. In the light state, fluorescence resonance energy transfer analyses demonstrated that deletion of the ZIP region increased the dissociation constant from ~0.15 to 0.6 µM, suggesting that intermolecular LOV-LOV and ZIP-ZIP interactions stabilized the dimeric forms. Our results suggest that synergistic interactions between the LOV and bZIP domains stabilize the monomeric form in the dark state and the dimeric form in the light state, which possibly contributes to the function of PZ as a BL-regulated molecular switch.

Blue light-induced dimerization of monomeric aureochrome-1 enhances its affinity for the target sequence.

Aureochrome-1 (AUREO1) is a blue light (BL) receptor that mediates the branching response in stramenopile alga, Vaucheria frigida. AUREO1 contains a basic leucine zipper (bZIP) domain in the central region and a light-oxygen-voltage sensing (LOV) domain at the C terminus, and has been suggested to function as a light-regulated transcription factor. We have previously reported that preparations of recombinant AUREO1 contained the complete coding sequence (full-length, FL) and N-terminal truncated protein (ZL) containing bZIP and LOV domains, and suggested that wild-type ZL (ZLwt2) was in a dimer form with intermolecular disulfide linkages at Cys(162) and Cys(182) (Hisatomi, O., Takeuchi, K., Zikihara, K., Ookubo, Y., Nakatani, Y., Takahashi, F., Tokutomi, S., and Kataoka, H. (2013) Plant Cell Physiol. 54, 93-106). In the present study, we report the photoreactions, oligomeric structures, and DNA binding of monomeric cysteine to serine-mutated ZL (ZLC2S), DTT-treated ZL (DTT-ZL), and FL (DTT-FL). Recombinant AUREO1 showed similar spectral properties and dark regeneration kinetics to those of dimeric ZLwt2. Dynamic light scattering and size exclusion chromatography revealed that ZLC2S and DTT-ZL were monomeric in the dark state. Dissociation of intermolecular disulfide bonds of ZLwt2 was in equilibrium with a midpoint oxidation-redox potential of approximately -245 ± 15 mV. BL induced the dimerization of monomeric ZL, which subsequently increased its affinity for the target sequence. Also, DTT-FL was monomeric in the dark state and underwent BL-induced dimerization, which led to formation of the FL2·DNA complex. Taken together, our results suggest that monomeric AUREO1 is present in vivo, with dimerization playing a key role in its role as a BL-regulated transcription factor.

A light-regulated bZIP module, photozipper, induces the binding of fused proteins to the target DNA sequence in a blue light-dependent manner.

Aureochrome-1 (AUREO1) has been identified as a blue light (BL) receptor responsible for the BL-induced blanching of a stramenopile alga, Vaucheria frigida. BL induces the dimerization of monomeric AUREO1, which subsequently increases its affinity for the target sequence. We made a synthetic gene encoding N-terminally truncated monomeric AUREO1 (Photozipper protein) containing a basic region/leucine zipper (bZIP) domain and a light-oxygen-voltage-sensing domain. In the present study, yellow fluorescent protein or mCherry protein was fused with the Photozipper (PZ) protein, and their oligomeric structures and DNA-binding were compared in the dark and light states. Dynamic light scattering and size exclusion chromatography demonstrated that the hydrodynamic radii and molecular masses of the fusion proteins increased upon BL illumination, suggesting that fusion PZs underwent BL-induced dimerization. Moreover, BL-induced dimerization enhanced their affinities for the target sequence. Taken together, PZ likely functions as a BL-regulated bZIP module in fusion proteins, and can possibly provide a new approach for controlling bZIP transcription factors.

Delayed Emergence from Total Intravenous Anesthesia Following Posterior Spinal Correction and Fusion for Scoliosis: A Case Report.

BACKGROUND Postoperative acute liver failure, a complication following spine surgery, can cause delayed emergence from total intravenous anesthesia. Here, we report a case of acute severe postoperative liver failure following posterior spinal correction and fusion in a patient with congenital scoliosis. CASE REPORT A girl's congenital scoliosis worsened, and posterior spinal correction and fusion was scheduled. General anesthesia was induced with sevoflurane, fentanyl, target-controlled-infusion with propofol, and rocuronium. General anesthesia was maintained using target-controlled-infusion with propofol and remifentanil. The operation was completed with no remarkable complications. The operative time was 516 min and the anesthesia time was 641 min in the prone position. Emergence from anesthesia was poor, and it took 68 min to remove the tracheal tube after discontinuation of the anesthetic agents. The patient was drowsy and was transferred to her room in a general ward without reporting any pain, nausea, or dyspnea. On postoperative day 1, the results of laboratory investigations were suggestive of acute liver failure; contrast-enhanced computed tomography revealed a poorly enhanced area in the umbilical portion of the left liver lobe portal vein, indicating ischemic liver damage. Although no additional treatment was administered for acute liver failure, the patient recovered over time, and laboratory values normalized. No other postoperative complications were observed, and the patient was discharged on postoperative day 1. CONCLUSIONS Delayed emergence from general anesthesia may be due to acute liver failure following posterior spinal correction and fusion. There are several possible causes of postoperative liver failure, including anesthetics, prone position, and spinal surgery.

Blue light-induced conformational changes in a light-regulated transcription factor, aureochrome-1.

Aureochrome-1 (AUREO1) is a blue light (BL) receptor that mediates the branching response in the stramenopile alga, Vaucheria frigida. AUREO1 harbors a basic leucine zipper (bZIP) domain at the N-terminus and a light-oxygen-voltage-sensing (LOV) domain within the C-terminal region, and has been suggested to function as a light-regulated transcription factor. To understand the molecular mechanism of AUREO1, we have prepared three recombinant proteins: a full-length AUREO1 (FL), an N-terminal truncated construct containing bZIP and LOV (ZL) and a LOV-only (LOV) construct. The constructs showed the same absorption and fluorescent spectra in the dark state and underwent the characteristic cyclic reaction as previously observed in LOV domains upon BL excitation. FL and ZL bound to DNA in a sequence-specific manner. BL appeared to induce a shift of the α-helical structure of the LOV domain to a ß-sheet structure, but did not alter the hydrodynamic radius (R(H)) of this domain. ZL formed a dimer possibly through disulfide linkages in the bZIP and the linker region between bZIP and LOV. BL induced an approximately 5% increase in the R(H) of ZL, although its secondary structure was unchanged. These results support a schema where BL-induced changes in the LOV domain may cause conformational changes in the bZIP and/or the linker of a dimeric ZL molecule. Since a 5% increase of the R(H) was also observed with the FL construct, BL may induce global conformational changes similar to those observed for ZL, and formation of the FL dimer may facilitate DNA binding.

Dimerization processes for light-regulated transcription factor Photozipper visualized by high-speed atomic force microscopy.

Dimerization is critical for transcription factors (TFs) to bind DNA and regulate a wide variety of cellular functions; however, the molecular mechanisms remain to be completely elucidated. Here, we used high-speed atomic force microscopy (HS-AFM) to observe the dimerization process for a photoresponsive TF Photozipper (PZ), which consists of light-oxygen-voltage-sensing (LOV) and basic-region-leucine-zipper (bZIP) domains. HS-AFM visualized not only the oligomeric states of PZ molecules forming monomers and dimers under controlled dark-light conditions but also the domain structures within each molecule. Successive AFM movies captured the dimerization process for an individual PZ molecule and the monomer-dimer reversible transition during dark-light cycling. Detailed AFM images of domain structures in PZ molecules demonstrated that the bZIP domain entangled under dark conditions was loosened owing to light illumination and fluctuated around the LOV domain. These observations revealed the role of the bZIP domain in the dimerization processes of a TF.

Photoreactions of aureochrome-1.

Aureochrome is a recently discovered blue light photosensor that controls a light-dependent morphology change. As a photosensor, it has a unique DNA binding domain (bZIP). Although the biological functions of aureochrome have been revealed, the fundamental photochemistry of this protein has not been elucidated. The photochemical reaction dynamics of the LOV (light, oxygen, or voltage) domain of aureochrome-1 (AUREO1-LOV) and the LOV domain with the bZIP domain (AUREO1-ZL) were studied by employing the transient-grating (TG) technique, using size-exclusion chromatography to verify results. For both samples, adduct formation takes place with a time constant of 2.8 µs. Although significant diffusion changes were observed for both AUREO1-LOV and AUREO1-ZL after adduct formation, the origins of these changes were significantly different. The TG signal of AUREO1-LOV was strongly concentration-dependent. From analysis of the signal, it was concluded that AUREO1-LOV exists in equilibrium between the monomer and dimer, and dimerization of the monomer is the main reaction, i.e., irradiation with blue light enhances the strength of the interdomain interaction. On the other hand, the reaction of AUREO1-ZL is independent of concentration, suggesting that an intraprotein conformational change occurs in the bZIP domain with a time constant of 160 ms. These results revealed the different reactions and roles of the two domains; the LOV domain acts as a photosensor, leading to a subsequent conformational change in the bZIP domain, which should change its ability to bind to DNA. A model is proposed that demonstrates how aureochrome uses blue light to control its affinity for DNA.

Transmission of light signals from the light-oxygen-voltage core via the hydrophobic region of the ß-sheet surface in aureochrome-1.

Light-Oxygen-Voltage (LOV) domains are responsible for detecting blue light (BL) and regulating the activities of effector domains in various organisms. Photozipper (PZ), an N-terminally truncated aureochrome-1 protein, contains a LOV domain and a basic leucin zipper (bZIP) domain and plays a role as a light-activatable transcription factor. PZ is monomeric in the dark state and undergoes non-covalent dimerization upon illumination with BL, subsequently increasing its affinity for the target DNA. To clarify the molecular mechanism of aureochromes, we prepared site-directed mutants of PZ and performed quantitative analyses in the dark and light states. Although the amino acid substitutions in the hinge region between the LOV core and A'α helix had minor effects on the dimerization and DNA-binding properties of PZ, the substitutions in the ß-sheet region of the LOV core and in the A'α helix significantly affected these properties. We found that light signals are transmitted from the LOV core to the effector bZIP domain via the hydrophobic residues on the ß-sheet. The light-induced conformational change possibly deforms the hydrophobic regions of the LOV core and induces the detachment of the A'α helix to expose the dimerization surface, likely activating the bZIP domain in a light-dependent manner.

Quantitative analyses of the equilibria among DNA complexes of a blue-light-regulated bZIP module, Photozipper.

Aureochrome1 is a blue-light-receptor protein identified in a stramenopile alga, Vaucheria frigida. Photozipper (PZ) is an N-terminally truncated, monomeric, V. frigida aureochrome1 fragment containing a basic leucine zipper (bZIP) domain and a light-oxygen-voltage (LOV)-sensing domain. PZ dimerizes upon photoexcitation and consequently increases its affinity for the target sequence. In the present study, to understand the equilibria among DNA complexes of PZ, DNA binding by PZ and mutational variants was quantitatively investigated by electrophoretic-mobility-shift assay and fluorescence-correlation spectroscopy in the dark and light states. DNA binding by PZ was sequence-specific and light-dependent. The half-maximal effective concentration of PZ for binding to the target DNA sequence was ~40 nM in the light, which was >10-fold less than the value in the dark. By contrast, the dimeric PZ-S2C variant (with intermolecular disulfide bonds) had higher affinity for the target sequence, with dissociation constants of ~4 nM, irrespective of the light conditions. Substitutions of Glu159 and Lys164 in the leucine zipper region decreased the affinity of PZ for the target sequence, especially in the light, suggesting that these residues form inter-helical salt bridges between leucine zipper regions, stabilizing the dimer-DNA complex. Our quantitative analyses of the equilibria in PZ-DNA-complex formation suggest that the blue-light-induced dimerization of LOV domains and coiled-coil formation by leucine zipper regions are the primary determinants of the affinity of PZ for the target sequence.

Flavin-Radical Formation in the Light-Oxygen-Voltage-Sensing Domain of the Photozipper Blue-light Sensor Protein.

Formation of the neutral flavin radical in the light-oxygen-voltage-sensing (LOV-sensing) domain of photozipper, based on VfAUREO1, was investigated by electron paramagnetic resonance spectroscopy. The flavin radical was observed in the presence of dithiothreitol by illumination of a LOV-domain mutant (C254S), in which a photoactive cysteine residue in close proximity to flavin was replaced with a serine. The radical did not form under low initial protein-concentration conditions (less than 20 µM). The flavin radicals accumulated with logistic time-dependent kinetics when the protein concentrations were higher than 30 µM. These results indicate that the radical is produced by concerted reactions involving protein interactions and that the radical is formed from the LOV dimer but not the LOV monomer. In contrast, logistic time dependencies were not observed for the sample adapted to the dark following radical formation by illumination, indicating that initialization of the proton pathway is essential for this fast sensing reaction.

Distribution and translocation of photoreceptor Gbetagamma-phosducin system in medaka retina.

Unlike other vertebrates, teleosts have rod- and cone-specific phosducins (PD-R and PD-C) in the retina. To evaluate the teleost Gbetagamma-PD systems, we isolated cDNAs encoding medaka Gbeta1 and GbetaC, which selectively expressed rods and cones. Immunohistochemical studies showed that the strong reactivity of GbetaC but not PD-C was detected in cone outer segments. In rod outer segments (ROS), PD-R reactivity was stronger in light-adapted retina than in dark-adapted retina. Western blot analyses of fractions torn from the cryosections showed that the PD-R concentration was low in dark-adapted ROS. It is suggested that PD-R is translocated to ROS and effectively downregulates the phototransduction cascade in light-adapted rods.

A third photoreceptor-specific GRK found in the retina of Oryzias latipes (Japanese killifish).

We previously reported that the teleost fish medaka (Oryzias latipes, Japanese killifish), possesses two kinds of G protein-coupled receptor kinases (GRKs) in the retina with different localizations: GRK7 (OlGRK-C) in cones and GRK1 (OlGRK-R1) in rods. To further clarify the diversity of teleost photoreceptor GRKs, we sought other medaka GRKs. We found an additional cDNA that encodes a second retina-specific GRK1 (OlGRK-R2). In situ hybridization experiments demonstrated that OlGRK-R2 mRNA is selectively expressed in rods. Sequence analysis of the Fugu rubripes genomic database unveiled a larger diversity of GRKs than previously expected. We also describe the light-dependent regulation of GRK1, a phenomenon that has not been found in other species. Immunocytochemical analysis indicated that OlGRK-R2 is localized in rod outer segments, independent of light condition. OlGRK-R1 is localized in the rod inner segments and synaptic termini of dark-adapted eyes, and moves to rod outer segments after light adaptation. Our studies suggest that the two medaka GRKs are not functionally redundant, and demonstrate a complicated light-dependent regulation of GRK1 in vivo.

Time-Resolved Detection of Light-Induced Dimerization of Monomeric Aureochrome-1 and Change in Affinity for DNA.

Aureochrome (Aureo) is a recently discovered blue light sensor protein initially from Vaucheria frigida, in which it controls blue light-dependent branch formation and/or development of a sex organ by a light-dependent change in the affinity for DNA. Although photochemical reactions of Aureo-LOV (LOV is a C-terminal light-oxygen-voltage domain) and the N-terminal truncated construct containing a bZIP (N-terminal basic leucine zipper domain) and a LOV domain have previously been reported, the reaction kinetics of the change in affinity for DNA have never been elucidated. The reactions of Aureo where the cysteines are replaced by serines (AureoCS) as well as the kinetics of the change in affinity for a target DNA are investigated in the time-domain. The dimerization rate constant is obtained as 2.8 × 10(4) M(-1) s(-1), which suggests that the photoinduced dimerization occurs in the LOV domain and the bZIP domain dimerizes using the interaction with DNA. Surprisingly, binding with the target DNA is completed very quickly, 7.7 × 10(4) M(-1) s(-1), which is faster than the protein dimerization rate. It is proposed that the nonspecific electrostatic interaction, which is observed as a weak binding with DNA, may play a role in the efficient searching for the target sequence within the DNA.

Downregulation of Otx2 in the dedifferentiated RPE cells of regenerating newt retina.

Cynops pyrrhogaster (the Japanese common newt) regenerates neural retina from retinal pigmented epithelium (RPE) cells. Otx2 is a transcription factor that is involved in RPE cell differentiation. To understand the role of Otx2 during transdifferentiation of RPE cells, we cloned a Cynops Otx2 cDNA, and explored its expression by RT-PCR, immunohistochemistry and in situ hybridization. The expression of Otx2 was compared with the localization of a proliferating cell marker (PCNA), RPE cell markers (RPE65, CRBP) and an RPE and Muller glial cell marker (CRALBP). At the early stage of regeneration, 2 to 3 cell layered regenerating retina consisting of pigmented cells uniformly expressed Otx2 and other markers. Following this stage, 4-cell layered regenerating retina consisted of two distinct layers, pigmented monolayer (the outer layer) attached to Bruch's membrane and presumptive neural retina (the inner layers). In the outer layer, Otx2 and CRBP expression was maintained and majority of cells lost PCNA expression. Some of cells maintained RPE65. In the inner layers, expression of Otx2, CRBP and RPE65 was downregulated, but a majority of those cells maintained PCNA expression. These results indicate that spatiotemporal regulation of Otx2 expression is consistent with those of RPE markers. Otx2 may play a pivotal role in maintenance and specification of RPE cells during neural retina regeneration. In contrast to RPE cell markers, CRALBP was expressed in both the pigmented and the de-pigmented layers. This observation implicates the appearance of Muller glial cells in an early phase of regenerating retina.

Opsin expression in adult, developing, and regenerating newt retinas.

Japanese common newts (Cynops pyrrhogaster) have an ability to regenerate their neural retina even as adults. Although extensive research has been carried out attempting to understand this retinal regeneration, the molecules characterized in newt retina are limited. We isolated cDNAs encoding three putative opsins (Cp-Rh, -LWS and -SWS1), in addition to Cp-SWS2 [Takahashi et al., FEBS Lett. 501 (2001) 151-155] from a cDNA library of adult newt retina. Our immunohistochemical and in situ hybridization studies demonstrated that Cp-Rh is selectively expressed in rods, whereas the other opsins are expressed in cones. The distribution of opsin mRNAs in normal and regenerated retinas is very similar. In both developing and regenerating retinas, Cp-Rh and its mRNA first appeared in immature rods at the beginning or just after the formation of plexiform layers. Cp-Rh was initially found isotropically in the plasma membrane, and then translocalized to the apical region along with the maturation of regenerating rods. This suggests that reorganization of the intracellular structure takes place during maturation of the regenerating newt photoreceptors.

Molecular evolution of proteins involved in vertebrate phototransduction.

Vision is one of the most important senses for vertebrates. As a result, vertebrates have evolved a highly organized system of retinal photoreceptors. Light triggers an enzymatic cascade, called the phototransduction cascade, that leads to the hyperpolarization of photoreceptors. It is expected that a systematic comparison of phototransduction cascades of various vertebrates can provide insights into the diversity of vertebrate photoreceptors and into the evolution of vertebrate vision. However, only a few attempts have been made to compare each phototransduction protein participating in this cascade. Here, we determine phylogenetic trees of the vertebrate phototransduction proteins and compare them. It is demonstrated that vertebrate opsin sequences fall into five fundamental subfamilies. It is speculated that this is crucial for the diversity of the spectral sensitivity observed in vertebrate photoreceptors and provides the vertebrates with the molecular tools to discriminate the color of incident light. Other phototransduction proteins can be classified into only a few subfamilies. Cones generally share isoforms of phototransduction proteins that are different from those found in rods. The difference in sensitivity to light between rods and cones is likely due to the difference in the molecular properties of these isoforms. The phototransduction proteins seem to have co-evolved as a system. Switching the expression of these isoforms may characterize individual vertebrate photoreceptors.