Crystal structure of heliorhodopsin.

Heliorhodopsins (HeRs) are a family of rhodopsins that was recently discovered using functional metagenomics1. They are widely present in bacteria, archaea, algae and algal viruses2,3. Although HeRs have seven predicted transmembrane helices and an all-trans retinal chromophore as in the type-1 (microbial) rhodopsin, they display less than 15% sequence identity with type-1 and type-2 (animal) rhodopsins. HeRs also exhibit the reverse orientation in the membrane compared with the other rhodopsins. Owing to the lack of structural information, little is known about the overall fold and the photoactivation mechanism of HeRs. Here we present the 2.4-Å-resolution structure of HeR from an uncultured Thermoplasmatales archaeon SG8-52-1 (GenBank sequence ID LSSD01000000). Structural and biophysical analyses reveal the similarities and differences between HeRs and type-1 microbial rhodopsins. The overall fold of HeR is similar to that of bacteriorhodopsin. A linear hydrophobic pocket in HeR accommodates a retinal configuration and isomerization as in the type-1 rhodopsin, although most of the residues constituting the pocket are divergent. Hydrophobic residues fill the space in the extracellular half of HeR, preventing the permeation of protons and ions. The structure reveals an unexpected lateral fenestration above the ß-ionone ring of the retinal chromophore, which has a critical role in capturing retinal from environment sources. Our study increases the understanding of the functions of HeRs, and the structural similarity and diversity among the microbial rhodopsins.

A distinct abundant group of microbial rhodopsins discovered using functional metagenomics.

Many organisms capture or sense sunlight using rhodopsin pigments1,2, which are integral membrane proteins that bind retinal chromophores. Rhodopsins comprise two distinct protein families 1 , type-1 (microbial rhodopsins) and type-2 (animal rhodopsins). The two families share similar topologies and contain seven transmembrane helices that form a pocket in which retinal is linked covalently as a protonated Schiff base to a lysine at the seventh transmembrane helix2,3. Type-1 and type-2 rhodopsins show little or no sequence similarity to each other, as a consequence of extensive divergence from a common ancestor or convergent evolution of similar structures 1 . Here we report a previously unknown and diverse family of rhodopsins-which we term the heliorhodopsins-that we identified using functional metagenomics and that are distantly related to type-1 rhodopsins. Heliorhodopsins are embedded in the membrane with their N termini facing the cell cytoplasm, an orientation that is opposite to that of type-1 or type-2 rhodopsins. Heliorhodopsins show photocycles that are longer than one second, which is suggestive of light-sensory activity. Heliorhodopsin photocycles accompany retinal isomerization and proton transfer, as in type-1 and type-2 rhodopsins, but protons are never released from the protein, even transiently. Heliorhodopsins are abundant and distributed globally; we detected them in Archaea, Bacteria, Eukarya and their viruses. Our findings reveal a previously unknown family of light-sensing rhodopsins that are widespread in the microbial world.

A Novel Color Switch of Microbial Rhodopsin.

Function of animal and microbial rhodopsins starts by light absorption of the retinal chromophore. The absorption maximum wavelength (λmax) of rhodopsins is determined by the energy gap between the electronically ground (S0) and first excited (S1) state of the retinal chromophore, and the color tuning mechanism is one of the central topics in rhodopsin research. "Color switches", color-determining residues, are red- and blue-shifting amino acids at the same position in two rhodopsins, whose exchange causes spectral blue- and red-shifts, respectively, in each rhodopsin. As mutation easily destroys elaborate chromophore-protein interactions, the known color switches in microbial rhodopsins are limited; the L/Q switch in C-helix (TM3), the A/TS switch in G-helix (TM7), and the G/P switch in F-helix (TM6). Here, we report a novel color switch of microbial rhodopsins, which is located in D-helix (TM4). In this color switch, the red- and blue-shifting amino acids are Asn (N) and Leu (L)/Ile (I), respectively. As Asn and Leu/Ile are polar and nonpolar amino acids, respectively, and the position is located near the ß-ionone ring, the N/LI switch matches the general rule of color tuning by polarity. The N/LI switch is also useful for optogenetics, as many ion-transporting rhodopsins contain blue-shifting amino acids, such as L and I, at that position.

Optogenetic reprogramming of carbon metabolism using light-powering microbial proton pump systems.

In microbial fermentative production, ATP regeneration, while crucial for cellular processes, conflicts with efficient target chemical production because ATP regeneration exhausts essential carbon sources also required for target chemical biosynthesis. To wrestle with this dilemma, we harnessed the power of microbial rhodopsins with light-driven proton pumping activity to supplement with ATP, thereby facilitating the bioproduction of various chemicals. We first demonstrated a photo-driven ATP supply and redistribution of metabolic carbon flows to target chemical synthesis by installing already-known delta rhodopsin (dR) in Escherichia coli. In addition, we identified novel rhodopsins with higher proton pumping activities than dR, and created an engineered cell for in vivo self-supply of the rhodopsin-activator, all-trans-retinal. Our concept exploiting the light-powering ATP supplier offers a potential increase in carbon use efficiency for microbial productions through metabolic reprogramming.

TAT Rhodopsin Is an Ultraviolet-Dependent Environmental pH Sensor.

In many rhodopsins, the retinal Schiff base pKa remains very high, ensuring Schiff base protonation captures visible light. Nevertheless, recently we found that TAT rhodopsin contains protonated and unprotonated forms at physiological pH. The protonated form displays a unique photochemical behavior in which the primary K intermediate returns to the original state within 10-5 s, and the lack of photocycle completion poses questions about the functional role of TAT rhodopsin. Here we studied the molecular properties of the protonated and unprotonated forms of the Schiff base in TAT rhodopsin. We confirmed no photointermediate formation at >10-5 s for the protonated form of TAT rhodopsin in microenvironments such as detergents, nanodiscs, and liposomes. In contrast, the unprotonated form features a very long photocycle with a time constant of 15 s. A low-temperature study revealed that the primary reaction of the unprotonated form is all-trans to 13-cis photoisomerization, which is usual, but with a proton transfer reaction occurring at 77 K, which is unusual. The active intermediate contains the unprotonated Schiff base as well as the resting state. Electrophysiological measurements excluded ion-transport activity for TAT rhodopsin, while transient outward proton movement only at an alkaline extracellular pH indicates that TAT rhodopsin senses the extracellular pH. On the basis of the findings presented here, we propose that TAT rhodopsin is an ultraviolet (UV)-dependent environmental pH sensor in marine bacteria. At acidic pH, absorbed visible light energy is quickly dissipated into heat without any function. In contrast, when the environmental pH becomes high, absorption of UV/blue light yields formation of the long-lived intermediates, possibly driving the signal transduction cascade in marine bacteria.

Molecular Properties and Optogenetic Applications of Enzymerhodopsins.

The cyclic nucleotides cAMP and cGMP are ubiquitous secondary messengers that regulate multiple biological functions including gene expression, differentiation, proliferation, and cell survival. In sensory neurons, cyclic nucleotides are responsible for signal modulation, amplification, and encoding. For spatial and temporal manipulation of cyclic nucleotide dynamics, optogenetics have a great advantage over pharmacological approaches. Enzymerhodopsins are a unique family of microbial rhodopsins. These molecules are made up of a membrane-embedded rhodopsin domain, which binds an all trans-retinal to form a chromophore, and a cytoplasmic water-soluble catalytic domain. To date, three kinds of molecules have been identified from lower eukaryotes such as fungi, algae, and flagellates. Among these, histidine kinase rhodopsin (HKR) is a light-inhibited guanylyl cyclase. Rhodopsin GC (Rh-GC) functions as a light-activated guanylyl cyclase, while rhodopsin PDE (Rh-PDE) functions as a light-activated phosphodiesterase that degrades cAMP and cGMP. These enzymerhodopsins have great potential in optogenetic applications for manipulating the intracellular cyclic nucleotide dynamics of living cells. Here we introduce the molecular function and applicability of these molecules.

Spectroscopic study of the transmembrane domain of a rhodopsin-phosphodiesterase fusion protein from a unicellular eukaryote.

The choanoflagellate Salpingoeca rosetta contains a chimeric rhodopsin protein composed of an N-terminal rhodopsin (Rh) domain and a C-terminal cyclic nucleotide phosphodiesterase (PDE) domain. The Rh-PDE enzyme light-dependently decreases the concentrations of cyclic nucleotides such as cGMP and cAMP. Photoexcitation of purified full-length Rh-PDE yields an "M" intermediate with a deprotonated Schiff base, and its recovery is much faster than that of the enzyme domain. To gain structural and mechanistic insights into the Rh domain, here we expressed and purified the transmembrane domain of Rh-PDE, Rh-PDE(TMD), and analyzed it with transient absorption, light-induced difference UV-visible, and FTIR spectroscopy methods. These analyses revealed that the "K" intermediate forms within 0.005 ms and converts into the M intermediate with a time constant of 4 ms, with the latter returning to the original state within 4 s. FTIR spectroscopy revealed that all-trans to 13-cis photoisomerization occurs as the primary event during which chromophore distortion is located at the middle of the polyene chain, allowing the Schiff base to form a stronger hydrogen bond. We also noted that the peptide backbone of the α-helix becomes deformed upon M intermediate formation. Results from site-directed mutagenesis suggested that Glu-164 is protonated and that Asp-292 acts as the only Schiff base counterion in Rh-PDE. A strong reduction of enzymatic activity in a D292N variant, but not in an E164Q variant, indicated an important catalytic role of the negative charge at Asp-292. Our findings provide further mechanistic insights into rhodopsin-mediated, light-dependent regulation of second-messenger levels in eukaryotic microbes.

Light-Driven Sodium-Pumping Rhodopsin: A New Concept of Active Transport.

Ion pumps perform active transport of ions by using energy. The active transport mechanism can be illustrated by the Panama Canal model, which considers two gates and a gain in energy. The Panama Canal model is consistent with the alternating access model that is used to describe active transport, in which the substrate ion is bound, energized, and released. It was generally accepted that energization occurs only for an ion-bound protein but not for an ion-unbound protein. Light-driven proton and chloride pumps, two of the best studied pumps, are represented by the Panama Canal model. In this case, light absorption takes place for the bound state of ions (proton and chloride ions) in the active center (protonated Schiff base of the retinal chromophore). In contrast, a recently discovered light-driven sodium pump, Krokinobacter eikastus rhodopsin 2 (KR2), is a unique active transporter that does not bind the transport substrate, the sodium ion, in its resting state. The molecular architecture and photoreaction cycle of the light-driven sodium pump are very similar to those of proton and chloride pumps, although sodium ions are actively transported without initial binding. Sodium uptake is a diffusive process, but the presence of two gates allows the unidirectional transport of sodium ions. In this sense, the light-driven sodium pump is also represented by a modified Panama Canal model. Current understanding of the light-driven sodium pump is reviewed.

A unique choanoflagellate enzyme rhodopsin exhibits light-dependent cyclic nucleotide phosphodiesterase activity.

Photoactivated adenylyl cyclase (PAC) and guanylyl cyclase rhodopsin increase the concentrations of intracellular cyclic nucleotides upon illumination, serving as promising second-generation tools in optogenetics. To broaden the arsenal of such tools, it is desirable to have light-activatable enzymes that can decrease cyclic nucleotide concentrations in cells. Here, we report on an unusual microbial rhodopsin that may be able to meet the demand. It is found in the choanoflagellate Salpingoeca rosetta and contains a C-terminal cyclic nucleotide phosphodiesterase (PDE) domain. We examined the enzymatic activity of the protein (named Rh-PDE) both in HEK293 membranes and whole cells. Although Rh-PDE was constitutively active in the dark, illumination increased its hydrolytic activity 1.4-fold toward cGMP and 1.6-fold toward cAMP, as measured in isolated crude membranes. Purified full-length Rh-PDE displayed maximal light absorption at 492 nm and formed the M intermediate with the deprotonated Schiff base upon illumination. The M state decayed to the parent spectral state in 7 s, producing long-lasting activation of the enzyme domain with increased activity. We discuss a possible mechanism of the Rh-PDE activation by light. Furthermore, Rh-PDE decreased cAMP concentration in HEK293 cells in a light-dependent manner and could do so repeatedly without losing activity. Thus, Rh-PDE may hold promise as a potential optogenetic tool for light control of intracellular cyclic nucleotides (e.g. to study cyclic nucleotide-associated signal transduction cascades).

Color-tuned channelrhodopsins for multiwavelength optogenetics.

Channelrhodopsin-2 is a light-gated ion channel and a major tool of optogenetics. It is used to control neuronal activity via blue light. Here we describe the construction of color-tuned high efficiency channelrhodopsins (ChRs), based on chimeras of Chlamydomonas channelrhodopsin-1 and Volvox channelrhodopsin-1. These variants show superb expression and plasma membrane integration, resulting in 3-fold larger photocurrents in HEK cells compared with channelrhodopsin-2. Further molecular engineering gave rise to chimeric variants with absorption maxima ranging from 526 to 545 nm, dovetailing well with maxima of channelrhodopsin-2 derivatives ranging from 461 to 492 nm. Additional kinetic fine-tuning led to derivatives in which the lifetimes of the open state range from 19 ms to 5 s. Finally, combining green- with blue-absorbing variants allowed independent activation of two distinct neural cell populations at 560 and 405 nm. This novel panel of channelrhodopsin variants may serve as an important toolkit element for dual-color cell stimulation in neural circuits.

Light-Driven Chloride and Sulfate Pump with Two Different Transport Modes.

Ion pumps are membrane proteins that actively translocate ions by using energy. All known pumps bind ions in the resting state, and external energy allows ion transport through protein structural changes. The light-driven sodium-ion pump Krokinobacter eikastus rhodopsin 2 (KR2) is an exceptional case in which ion binding follows the energy input. In this study, we report another case of this unusual transport mode. The NTQ rhodopsin from Alteribacter aurantiacus (AaClR) is a natural light-driven chloride pump, in which the chloride ion binds to the resting state. AaClR is also able to pump sulfate ions, though the pump efficiency is much lower for sulfate ions than for chloride ions. Detailed spectroscopic analysis revealed no binding of the sulfate ion to the resting state of AaClR, indicating that binding of the substrate (sulfate ion) to the resting state is not necessary for active transport. This property of the AaClR sulfate pump is similar to that of the KR2 sodium pump. Photocycle dynamics of the AaClR sulfate pump resemble a non-functional cycle in the absence of anions. Despite this, flash photolysis and difference Fourier transform infrared spectroscopy suggest transient binding of the sulfate ion to AaClR. The molecular mechanism of this unusual active transport by AaClR is discussed.

A light-gated cation channel with high reactivity to weak light.

The cryptophyte algae, Guillardia theta, possesses 46 genes that are homologous to microbial rhodopsins. Five of them are functionally light-gated cation channelrhodopsins (GtCCR1-5) that are phylogenetically distinct from chlorophyte channelrhodopsins (ChRs) such as ChR2 from Chlamydomonas reinhardtii. In this study, we report the ion channel properties of these five CCRs and compared them with ChR2 and other ChRs widely used in optogenetics. We revealed that light sensitivity varied among GtCCR1-5, in which GtCCR1-3 exhibited an apparent EC50 of 0.21-1.16 mW/mm2, similar to that of ChR2, whereas GtCCR4 and GtCCR5 possess two EC50s, one of which is significantly small (0.025 and 0.032 mW/mm2). GtCCR4 is able to trigger action potentials in high temporal resolution, similar to ChR2, but requires lower light power, when expressed in cortical neurons. Moreover, a high light-sensitive response was observed when GtCCR4 was introduced into blind retina ganglion cells of rd1, a mouse model of retinitis pigmentosa. Thus, GtCCR4 provides optogenetic neuronal activation with high light sensitivity and temporal precision.

Optogenetic manipulation of neuronal and cardiomyocyte functions in zebrafish using microbial rhodopsins and adenylyl cyclases.

Even though microbial photosensitive proteins have been used for optogenetics, their use should be optimized to precisely control cell and tissue functions in vivo. We exploited GtCCR4 and KnChR, cation channelrhodopsins from algae, BeGC1, a guanylyl cyclase rhodopsin from a fungus, and photoactivated adenylyl cyclases (PACs) from cyanobacteria (OaPAC) or bacteria (bPAC), to control cell functions in zebrafish. Optical activation of GtCCR4 and KnChR in the hindbrain reticulospinal V2a neurons, which are involved in locomotion, induced swimming behavior at relatively short latencies, whereas activation of BeGC1 or PACs achieved it at long latencies. Activation of GtCCR4 and KnChR in cardiomyocytes induced cardiac arrest, whereas activation of bPAC gradually induced bradycardia. KnChR activation led to an increase in intracellular Ca2+ in the heart, suggesting that depolarization caused cardiac arrest. These data suggest that these optogenetic tools can be used to reveal the function and regulation of zebrafish neurons and cardiomyocytes.

Red-shifted optogenetic excitation: a tool for fast neural control derived from Volvox carteri.

The introduction of two microbial opsin-based tools, channelrhodopsin-2 (ChR2) and halorhodopsin (NpHR), to neuroscience has generated interest in fast, multimodal, cell type-specific neural circuit control. Here we describe a cation-conducting channelrhodopsin (VChR1) from Volvox carteri that can drive spiking at 589 nm, with excitation maximum red-shifted approximately 70 nm compared with ChR2. These results demonstrate fast photostimulation with yellow light, thereby defining a functionally distinct third category of microbial rhodopsin proteins.

Unusual Photoisomerization Pathway in a Near-Infrared Light Absorbing Enzymerhodopsin.

Microbial and animal rhodopsins possess retinal chromophores which capture light and normally photoisomerize from all-trans to 13-cis and from 11-cis to all-trans-retinal, respectively. Here, we show that a near-infrared light-absorbing enzymerhodopsin from Obelidium mucronatum (OmNeoR) contains the all-trans form in the dark but isomerizes into the 7-cis form upon illumination. The photoproduct (λmax = 372 nm; P372) possesses a deprotonated Schiff base, and the system exhibits a bistable nature. The photochemistry of OmNeoR was arrested at <270 K, indicating the presence of a potential barrier in the excited state. Formation of P372 is accompanied by protonation changes of protonated carboxylic acids and peptide backbone changes of an α-helix. Photoisomerization from the all-trans to 7-cis retinal conformation rarely occurs in any solvent and protein environments; thus, the present study reports on a novel photochemistry mediated by a microbial rhodopsin, leading from the all-trans to 7-cis form selectively.

Proton-transporting heliorhodopsins from marine giant viruses.

Rhodopsins convert light into signals and energy in animals and microbes. Heliorhodopsins (HeRs), a recently discovered new rhodopsin family, are widely present in archaea, bacteria, unicellular eukaryotes, and giant viruses, but their function remains unknown. Here, we report that a viral HeR from Emiliania huxleyi virus 202 (V2HeR3) is a light-activated proton transporter. V2HeR3 absorbs blue-green light, and the active intermediate contains the deprotonated retinal Schiff base. Site-directed mutagenesis study revealed that E191 in TM6 constitutes the gate together with the retinal Schiff base. E205 and E215 form a PAG of the Schiff base, and mutations at these positions converted the protein into an outward proton pump. Three environmental viral HeRs from the same group as well as a more distantly related HeR exhibited similar proton-transport activity, indicating that HeR functions might be diverse similarly to type-1 microbial rhodopsins. Some strains of E. huxleyi contain one HeR that is related to the viral HeRs, while its viruses EhV-201 and EhV-202 contain two and three HeRs, respectively. Except for V2HeR3 from EhV-202, none of these proteins exhibit ion transport activity. Thus, when expressed in the E. huxleyi cell membranes, only V2HeR3 has the potential to depolarize the host cells by light, possibly to overcome the host defense mechanisms or to prevent superinfection. The neuronal activity generated by V2HeR3 suggests that it can potentially be used as an optogenetic tool, similarly to type-1 microbial rhodopsins.

Ion transport activity and optogenetics capability of light-driven Na+-pump KR2.

KR2 from marine bacteria Krokinobacter eikastus is a light-driven Na+ pumping rhodopsin family (NaRs) member that actively transports Na+ and/or H+ depending on the ionic state. We here report electrophysiological studies on KR2 to address ion-transport properties under various electrochemical potentials of Δ[Na+], ΔpH, membrane voltage and light quality, because the contributions of these on the pumping activity were less understood so far. After transient expression of KR2 in mammalian cultured cells (ND7/23 cells), photocurrents were measured by whole-cell patch clamp under various intracellular Na+ and pH conditions. When KR2 was continuously illuminated with LED light, two distinct time constants were obtained depending on the Na+ concentration. KR2 exhibited slow ion transport (τoff of 28 ms) below 1.1 mM NaCl and rapid transport (τoff of 11 ms) above 11 mM NaCl. This indicates distinct transporting kinetics of H+ and Na+. Photocurrent amplitude (current density) depends on the intracellular Na+ concentration, as is expected for a Na+ pump. The M-intermediate in the photocycle of KR2 could be transferred into the dark state without net ion transport by blue light illumination on top of green light. The M intermediate was stabilized by higher membrane voltage. Furthermore, we assessed the optogenetic silencing effect of rat cortical neurons after expressing KR2. Light power dependency revealed that action potential was profoundly inhibited by 1.5 mW/mm2 green light illumination, confirming the ability to apply KR2 as an optogenetics silencer.

Specific residues in the cytoplasmic domain modulate photocurrent kinetics of channelrhodopsin from Klebsormidium nitens.

Channelrhodopsins (ChRs) are light-gated ion channels extensively applied as optogenetics tools for manipulating neuronal activity. All currently known ChRs comprise a large cytoplasmic domain, whose function is elusive. Here, we report the cation channel properties of KnChR, one of the photoreceptors from a filamentous terrestrial alga Klebsormidium nitens, and demonstrate that the cytoplasmic domain of KnChR modulates the ion channel properties. KnChR is constituted of a 7-transmembrane domain forming a channel pore, followed by a C-terminus moiety encoding a peptidoglycan binding domain (FimV). Notably, the channel closure rate was affected by the C-terminus moiety. Truncation of the moiety to various lengths prolonged the channel open lifetime by more than 10-fold. Two Arginine residues (R287 and R291) are crucial for altering the photocurrent kinetics. We propose that electrostatic interaction between the rhodopsin domain and the C-terminus domain accelerates the channel kinetics. Additionally, maximal sensitivity was exhibited at 430 and 460 nm, the former making KnChR one of the most blue-shifted ChRs characterized thus far, serving as a novel prototype for studying the molecular mechanism of color tuning of the ChRs. Furthermore, KnChR would expand the optogenetics tool kit, especially for dual light applications when short-wavelength excitation is required.

Remote control of neural function by X-ray-induced scintillation.

Scintillators emit visible luminescence when irradiated with X-rays. Given the unlimited tissue penetration of X-rays, the employment of scintillators could enable remote optogenetic control of neural functions at any depth of the brain. Here we show that a yellow-emitting inorganic scintillator, Ce-doped Gd3(Al,Ga)5O12 (Ce:GAGG), can effectively activate red-shifted excitatory and inhibitory opsins, ChRmine and GtACR1, respectively. Using injectable Ce:GAGG microparticles, we successfully activated and inhibited midbrain dopamine neurons in freely moving mice by X-ray irradiation, producing bidirectional modulation of place preference behavior. Ce:GAGG microparticles are non-cytotoxic and biocompatible, allowing for chronic implantation. Pulsed X-ray irradiation at a clinical dose level is sufficient to elicit behavioral changes without reducing the number of radiosensitive cells in the brain and bone marrow. Thus, scintillator-mediated optogenetics enables minimally invasive, wireless control of cellular functions at any tissue depth in living animals, expanding X-ray applications to functional studies of biology and medicine.

Molecular Properties of New Enzyme Rhodopsins with Phosphodiesterase Activity.

The choanoflagellate Salpingoeca rosetta contains a chimeric rhodopsin protein composed of an N-terminal rhodopsin (Rh) domain and a C-terminal cyclic nucleotide phosphodiesterase (PDE) domain. The Rh-PDE enzyme (SrRh-PDE), which decreases the concentrations of cyclic nucleotides such as cGMP and cAMP in light, is a useful tool in optogenetics. Recently, eight additional Rh-PDE enzymes were found in choanoflagellate species, four from Choanoeca flexa and the other four from other species. In this paper, we studied the molecular properties of these new Rh-PDEs, which were compared with SrRh-PDE. Upon expression in HEK293 cells, four Rh-PDE proteins, including CfRh-PDE2 and CfRh-PDE3, exhibited no PDE activity when assessed by in-cell measurements and in vitro HPLC analysis. On the other hand, CfRh-PDE1 showed light-dependent PDE activity toward cGMP, which absorbed maximally at 491 nm. Therefore, CfRh-PDE1 is presumably responsible for colony inversion in C. flexa by absorbing blue-green light. The molecular properties of MrRh-PDE were similar to those of SrRh-PDE, although the λmax of MrRh-PDE (516 nm) was considerably red-shifted from that of SrRh-PDE (492 nm). One Rh-PDE, AsRh-PDE, did not contain the retinal-binding Lys at TM7 and showed cAMP-specific PDE activity both in the dark and light. These results provide mechanistic insight into rhodopsin-mediated, light-dependent regulation of second-messenger levels in eukaryotic microbes.