Enzymatic vitamin A2 production enables red-shifted optogenetics

Optogenetics is a technology using light-sensitive proteins to control signaling pathways and physiological processes in cells and organs and has been applied in neuroscience, cardiovascular sciences, and many other research fields. Most commonly used optogenetic actuators are sensitive to blue and green light, but red-light activation would allow better tissue penetration and less phototoxicity. Cyp27c1 is a recently deorphanized cytochrome P450 enzyme that converts vitamin A1 to vitamin A2, thereby red-shifting the spectral sensitivity of visual pigments and enabling near-infrared vision in some aquatic species. Here, we investigated the ability of Cyp27c1-generated vitamin A2 to induce a shift in spectral sensitivity of the light-gated ion channel Channelrhodopsin-2 (ChR2) and its red-shifted homolog ReaChR. We used patch clamp to measure photocurrents at specific wavelengths in HEK 293 cells expressing ChR2 or ReaChR. Vitamin A2 incubation red-shifted the wavelength for half-maximal currents (λ50%) by 6.8 nm for ChR2 and 12.4 nm for ReaChR. Overexpression of Cyp27c1 in HEK 293 cells showed mitochondrial localization, and HPLC analysis showed conversion of vitamin A1 to vitamin A2. Notably, the λ50% of ChR2 photocurrents was red-shifted by 10.5 nm, and normalized photocurrents at 550 nm were about twofold larger with Cyp27c1 expression. Similarly, Cyp27c1 shifted the λ50% of ReaChR photocurrents by 14.3 nm and increased normalized photocurrents at 650 nm almost threefold. Since vitamin A2 incubation is not a realistic option for in vivo applications and expression of Cyp27c1 leads to a greater red-shift in spectral sensitivity, we propose co-expression of this enzyme as a novel strategy for red-shifted optogenetics.


Introduction
Optogenetics is a technique that involves the use of light to control the function of genetically modified cells or organs with light-sensitive proteins.In the last decade, optogenetics has become a powerful method for light-induced modulation of electrical excitability, calcium influx, or stimulation of intracellular signaling pathways with high temporal and spatial precision [9].Several optogenetic actuators of the rhodopsin family containing light-gated ion channels or pumps have been described and used for various applications [3,4,9,21].Among these, ChR2, a light-induced cation channel, was used to depolarize cardiomyocytes in vitro and in the intact mouse heart, enabling pacing the whole heart [6].Using stronger, spatially extended, and longer periods of illumination, ChR2 can also be used to defibrillate the heart and to terminate ventricular arrhythmia if sufficient transmural activation of ChR2 is achieved [5].
ChR2 and its homologs are maximally activated by light between 450 nm and 545 nm [20].However, light in this range has limited organ penetration because it is strongly absorbed and scattered by tissue and blood [5,17].Since red wavelengths are less readily absorbed, opsins with spectral sensitivity in the red to near-infrared range (650 nm-900 nm) would enable better tissue penetrance [7,17].Several red-shifted channelrhodopsin variants have been developed by mutagenesis and screening, but most have less optimal properties such as lower expression levels and reduced photocurrents, or slower gating kinetics than the classical ChR2 [7,18,28].One promising red-shifted homolog is ReaChR, with an activation maximum between 590 and 630 nm when measuring stationary plateau photocurrents [15,19].
Another strategy for achieving red-shifted sensitivity of optogenetic actuators would be to exchange the chromophore of the optogenetic actuator [27,28].Vitamin A 1 -derived alltrans-retinal, the common chromophore in microbial opsins, can be replaced by vitamin A 2 -derived all-trans 3,4-didehydroretinal, which has a red-shifted absorption spectrum due to an extended system of conjugated double bonds [24,27].The use of this chromophore in photoreceptors in coldblooded vertebrates enhances vision in turbid aquatic environments where long wavelength light predominates [14].Application of high concentrations of exogenous all-trans 3,4-didehydroretinal to ChR2 was shown to result in a 30-40 nm red-shift of half-maximal currents [28].Nevertheless, substitution of all-trans 3,4-didehydroretinal is not a convenient option for optogenetic stimulation in living organisms because endogenous vitamin A 1 in the form of all-transretinol is the predominant form in the mammalian system [10,22,29,31] and would outcompete exogenously supplied vitamin A 2 [28].
Recently, the enzyme responsible for converting vitamin A 1 to A 2 in the visual pigments of some fish and amphibians was discovered to be Cyp27c1, a dehydrogenase belonging to the Cytochrome P450 family [10].Here, we show that the co-expression of Cyp27c1 with an optogenetic actuator provides a novel strategy to achieve red-shifted optogenetics.We expressed Cyp27c1 together with ChR2 as well as with the red-shifted homolog ReaChR in HEK 293 cells and analyzed the spectral sensitivity of photocurrents.We showed that Cyp27c1 overexpression in HEK cells results in the conversion of vitamin A 1 to A 2 , leading to a redshift in the spectral sensitivity of both ChR2 and ReaChR channelrhodopsins.

Generation of the CAG CYP27c1 EGFP Vector
To stably express zebrafish (Danio rerio) Cyp27c1 we engineered an expression vector by digesting the AAV_pVDM2_ Dr_Cyp vector [10] containing Cyp27c1 and EGFP linked by a T2A self-cleaving peptide with BlpI and BsrGI.The resulting 3009 bp fragment was subcloned into the 5895 bp fragment of the pCAG hChR2-EYFP vector [6] digested with the same enzymes and containing a neomycin selection cassette.The resulting vector CAG-Cyp27c1-EGFP was verified by restriction enzyme analysis and sequencing.The pEGFP-N1_ReachR_mCerulean vector was received from J. Vierock for expression of ReaChR mCerulean under the control of a CMV promoter.

Patch clamp analysis of photocurrents
Patch clamp recordings were performed using an EPC10 amplifier (Heka) at 10 kHz sampling rate on a Nikon Ti2 microscope with 20x objective (S Fluor DIC M/N2 Nikon) at 35 ± 2°C with an external solution of (in mM) 140 NaCl, 5.4 KCl, 1.8 CaCl 2 , 2 MgCl 2 , 10 glucose, 10 Hepes (pH 7.4, NaOH), and an internal solution of 50 KCl, 80 K-aspartate, 1 MgCl 2 , 3 MgATP, 10 EGTA, 10 HEPES (pH 7.2, KOH).Pipettes were pulled from borosilicate glass (BF 150-86-10, Scientific Products) at a tip resistance of 4-6 MΩ using a P-1000 puller (Sutter Instrument).Only ChR2-EYFP or ReaChR-Cerulean positive cells were investigated.Light was generated at 10 nm wavelength steps with a Xenon arc lamp-based monochromator (Optoscan, Cairn) controlled by the patch clamp amplifier and a custom-coded microcontroller (Arduino) to obtain a uniform slit bandwidth of 30 nm.The activation spectrum was analyzed from 480 nm to 600 nm for ChR2 nm and from 590 nm to 700 nm for ReaChR.Light intensities were calibrated at the objective plane using a power meter (PM100A with S170C sensor, Thorlabs) and reported in Table 1.
Photocurrents were evoked every 6 s at a holding potential of -40 mV and steady-state currents were measured at the end of a 500 ms light pulse (300-495 ms after the start of illumination) subtracted by baseline currents (250-475 ms after end of illumination).Photocurrents were normalized to the cell capacity.Because we measured saturating photocurrents (see also discussion), photocurrents were not normalized to differences in light intensity.Photocurrents are presented as absolute currents, or to account for cell-to-cell variability in expression, for spectral comparisons photocurrents were normalized to the maximal value of each cell.

High performance liquid chromatography (HPLC)
HEK 293 cells incubated in vitamin A 1 (all-trans-retinol) were detached, centrifuged, frozen on dry ice and stored at -80 o C. Samples were subsequently thawed and homogenized in cold 0.9% NaCl solution by sonication.A small portion of the homogenized sample was used to measure protein content for normalization.Retinaldehydes were derivatized and analyzed by HPLC as previously described [30].Retinoids were identified by comparison to retinol and 3,4-didehydroretinol standards as well as the published literature [1,12,23].Standard curves were generated using retinol (R7632, Sigma) for the quantification of A 1 retinols (all-trans-retinol and 13-cis-retinol) and 3,4-didehydroretinol (sc-209587, Santa Cruz Biotechnology) for the quantification of A 2 retinols (all-trans-3,4-didehydroretinol and 13-cis 3,4-didehydroretinol).Calculations were made based on previously published extinction coefficients [2].Because incubation of cells with 3.5 and 35 μM vitamin A 1 showed similar results, we pooled these data for statistical analysis of the Cyp27c1 effect on vitamin A 2 production.

Statistical analysis
Data were analyzed offline using Fitmaster (Heka), Graph Pad Prism 6 (GraphPad) and Origin (OriginLab) software.Data are shown as mean ± SEM.Statistical analysis was performed with unpaired t-test or one-way ANOVA with Tukey's multiple comparison test.A p value ≤ 0.05 was considered statistically significant.

Vitamin A 2 incubation causes a red-shift in spectral sensitivity
In order to analyze the effect of exogenously supplied vitamin A 1 or vitamin A 2 on the spectral sensitivity of ChR2, we incubated HEK 293 cells expressing ChR2 in fusion with EYFP (Fig. 1a) with vitamin A 1 (A1, 25 μM) or vitamin A 2 (A2, 25 μM) and measured photocurrents in response to exposure to light of varying wavelengths.We supplied vitamin A 1 and A 2 as the retinol form to mimic the in vivo situation where the majority of circulating vitamin A is in the alcohol form.We assume that the alcohol form is converted by cells at low rates into the aldehyde form by endogenous dehydrogenases and then taken up by the optogenetic actuators (see Discussion).The response to 480 nm light is shown in Fig. 1b.To precisely control the concentration of vitamin A 1 or A 2 in the medium, we used the serum-free medium Panserin 293A, which contains 0.4 μM vitamin A 1 (as all-trans-retinol) because standard FCS contains undefined quantities of vitamin A. As shown previously [28], vitamin A 2 incubation led to a red-shift of the spectral sensitivity of ChR2 (Fig. 1c, arrow) and increased photocurrents at wavelengths between 525 nm and 600 nm (Fig. 1d).The wavelength at which half-maximal currents are obtained (λ 50% ) was red-shifted by 6.8 nm after vitamin A 2 incubation.At 550 nm, where the effect can be clearly seen, cells incubated with vitamin A 2 reached 24.5 ± 0.5%, whereas only 19.2 ± 1.0% of the maximal photocurrent was measured in cells incubated with vitamin A 1 (Fig. 1e).Absolute photocurrents were not different (Fig. 1f) most likely because maximal photocurrents were larger in vitamin A 1 .than in vitamin A 2 , which was discussed before [8].
Next, we investigated the effect of vitamin A 2 on the red-shifted channelrhodopsin variant ReaChR.Consistent with our ChR2 experiments (Fig. 1), HEK 293 cells with stable expression of ReaChR in fusion to Cerulean (Fig. 2a,  b) showed a significant red-shift of 12.4 nm of λ 50% after incubation with vitamin A 2 (Fig. 2c).ReaChR-expressing cells incubated with vitamin A 2 showed ~2.5-fold higher photocurrents at the long wavelength edge (~660 nm) of spectral sensitivity than those incubated with vitamin A 1 (Fig. 2d).For instance, cells incubated with vitamin A 1 achieved 11.0 ± 0.7% at 650 nm, whereas cells incubated with vitamin A 2 attained 25.7 ± 1.4% of their maximal photocurrent (Fig. 2e).Absolute photocurrents were not different (Fig. 2f) most likely because maximal photocurrents were larger in vitamin A 1 .Having shown that vitamin A 2 is able to red-shift spectral sensitivity of ChR2 and ReaChR, we expect similar effects of vitamin A 2 application in other channelrhodopsin variants.

Cyp27c1 converts vitamin A 1 to vitamin A 2
For in vivo optogenetic applications, the use of exogenously applied vitamin A 2 as a chromophore may not be feasible due to the predominance of vitamin A 1 in mammalian serum and tissues [10,22,29,31].In order to take advantage of the red-shifting effect of vitamin A 2 in the presence of vitamin A 1 , we used the vitamin A 1 -to-A 2 converting enzyme Cyp27c1 [10].We generated a HEK 293 cell line stably expressing Cyp27c1 under the control of the CAG promoter (Fig. 3a) using neomycin selection (Fig. 3b).Comparison of EGFP-fluorescence signals in Cyp27c1-expressing cells (Fig. 3c, green) with anti-Cyp27c1 (Fig. 3c, red) and mitochondrial staining (Fig. 3c, white) suggests mitochondrial localization of Cyp27c1.To confirm the functionality of Cyp27c1 in HEK 293 cells, we performed HPLC analysis in lysates of HEK 293 cells expressing Cyp27c1 and wild-type controls and incubated them with 3.5 or 35 μM vitamin A 1 for 24 h.HPLC analysis showed the presence of both vitamin A 1 and A 2 in cells expressing Cyp27c1 but only vitamin A 1 in control cells (Fig. 3, d-f).

Cyp27c1 red-shifts the spectral sensitivity of ChR2
To analyze the effect of Cyp27c1 on the spectral sensitivity of the most commonly used optogenetic actuator, we transiently expressed ChR2-EYFP in Cyp27c1-expressing (Fig. 4a) and wild-type control HEK 293 cell lines.Analysis of photocurrents at different wavelengths showed that co-expression of Cyp27c1 leads to a red-shift of the spectral sensitivity (Fig. 4b, arrow) which was even larger than that observed after incubation with vitamin A 2 (Fig. 1c).Interestingly, the red-shifting effect of Cyp27c1 could be reversed by adding 5 μM vitamin A 1 to the culture medium, suggesting that the higher concentration of vitamin A 1 led to replacement of the vitamin A 2 chromophore (Fig. 4b).Photocurrents in Cyp27c1-expressing cells were up to three times higher at the long wavelength end of spectral sensitivity than control cells (Fig. 4c).Analysis of λ 50% for each cell individually showed a shift of 10.5 nm to longer wavelengths by Cyp27c1 expression (Fig. 4d), which underscores the potential benefits of Cyp27c1 co-expression for optogenetic applications.For example, at 550 nm, cells without Cyp27c1 expression reached only 15.2 ± 0.5% of their maximal currents (Fig. 4e), while Cyp27c1 expressing cells showed almost one-third of maximal currents (Fig. 4e, 30.4 ± 1.1%).Similarly, absolute photocurrents increased from 1.0 ± 0.1 pA/pF to 2.0 ± 0.2 pA/pF by Cyp27c1 expression Fig. 4f).co-expressing ReaChR and Cyp27c1 (Fig. 5a) showed a significant red shift of spectral sensetivity compared to control cells without Cyp27c1 co-expression (Fig. 5b, arrow).Adding vitamin A 1 (5 μM) reversed the effect, indicating replacement of vitamin A 2 -derived chromophore by A 1 .(Fig. 5b).Photocurrents of Cyp27c1-expressing cells were up to four times higher at wavelengths between 630 nm and 690 nm in comparison to cells without Cyp27c1 expression (Fig. 5c).For example, at 650 nm, control cells only achieved 9.9 ± 1.3% of the maximal currents whereas 29.6 ± 4.2% of maximal currents was seen in Cyp27c1 expressing cells (Fig. 5e).Similarly, absolute photocurrents increased from 0.3 ± 0.1 pA/pF to 2.3 ± 0.3 pA/pF by Cyp27c1 expression (Fig. 5f).Analysis of λ 50% for each cell individually showed 635.0 ± 3.1 nm for Cyp27c1 expressing cells and 620.7 ± 1.4 nm for control cells (Fig. 5d), which constitutes a Cyp27c1-induced redshift of λ 50% of 14.3 nm.

Discussion
In this study, we explored the idea of red-shifting the spectral sensitivity of optogenetic actuators by co-expression of a vitamin A 1 -to-A 2 converting enzyme, Cyp27c1.Consistent with the findings of Sineshchekov et al. [28], we showed that substitution of vitamin A 1 with vitamin A 2 leads to a red-shift of the spectral sensitivity of optogenetic actuators in living cells.Cyp27c1 was recently discovered to be the enzyme responsible for an enhancing near-infrared visual sensitivity by converting vitamin A 1 to vitamin A 2 in the visual pigments of aquatic vertebrates [10].Thus, we here propose enzymatic vitamin A 2 production by Cyp27c1 as a new method to red-shift the spectral sensitivity of optogenetic actuators without the need for supplying exogenous vitamin A 2 .Since longer wavelength light is less scattered and absorbed by tissue [5,17], optogenetic actuators with spectral sensitivity in the red to near-infrared therapeutic window (650 nm-900 nm) can facilitate actuator operability at greater tissue depth.Several red-shifted channelrhodopsin variants have been developed from different species and using mutagenesis, but most have less optimal properties than ChR2 with respect to expression, kinetics, or ion selectivity [7,18,28].So far, there is no evidence that the vitamin A 2 chromophore significantly alters fundamental functions of optogenetic actuators other than their spectral sensitivity [28], although maximum photosensitivity of A 2 -based visual pigments may be reduced compared to A 1 -based pigments [8].Thus, intracellular vitamin A 2 production by Cyp27c1 is a promising alternative strategy to red-shift the spectral sensitivity of optogenetic actuators.
Sineshchekov et al. [28] describe a red-shift in the spectral sensitivity of peak photocurrents by ~30 nm for the channelrhodopsin variants CrChR1, CrChR2, CaChR1 and MvChR1 in HEK 293 cells after incubation with vitamin A 2 in aldehyde form.However, our experiments with ChR2 and ReaChR showed only a 6.8 nm, and 12.4 nm shift in plateau photocurrents using identical vitamin A 2 concentrations (25 μM), but in the alcohol form.Both differences (peak vs plateau and retinol vs retinal) might have contributed to the less pronounced red-shift we observed.Importantly, we specifically investigated the effect of Cyp27c1 on plateau stationary photocurrents because many optogenetic applications, including defibrillation [5] or seizure control, require not a single light pulse with peak photocurrents but repetitive or constant light-induced depolarization [5], and in this situation, peak photocurrents are desensitized [19,20].
In contrast to earlier work that supplemented the oxidized versions of vitamin A 1 (all-trans-retinal) and vitamin A 2 (alltrans 3,4-didehydroretinal, not commercially available) [27,28] we have supplied the reduced form (all-trans-retinol) because it is the dominant form in serum and tissue [10,22,29,31] and is only converted to retinal in the eye by enzymes of the visual cycle [13].Also, Cyp27c1 most efficiently catalyzes the conversion of retinol [10].Thus, our findings in cell culture using retinol can be better transferred to the in vivo situation.Furthermore, all-trans-retinol in Panserin 293A medium is sufficient to generate large photocurrents in HEK293 cells.This is most likely due to the interconversion of retinal and retinol forms by endogenous dehydrogenases [13] such as the retinol dehydrogenase (RDH) 14, which is highly expressed in HEK293 cells [25].We were not able to detect all-trans-retinal in HEK293 cells fed with all-transretinol by HPLC analysis after oximes derivatization (data not shown).However, the presence of photocurrents proofs that these small undetectable amounts of retinal generated by RDHs are sufficient as chromophore for microbial opsins.This is not surprising because, in contrast to bleaching opsins, which require a constant supply of retinal aldehyde for recovery aver every photocycle, ChR2 and other microbial opsins do not dissociate from the retinal molecule during the photocycle.Interestingly, Sineshchekov et al. showed that the shift in spectral sensitivity due to vitamin A 2 incubation correlated with the vitamin A 2 /A 1 ratio in the medium [28], indicating a competition and similar binding affinities of both vitamins in the binding pocket of optogenetic actuators.The hypothesis of a vitamin A 2 /A 1 competition is supported by our findings that the Cyp27c1-induced red-shift of spectral sensitivity can be reversed by elevating the vitamin A 1 concentration (Fig. 4b,d, Fig. 5b,d).Thus, exogenous vitamin A 2 application will not be an option for in vivo optogenetic applications because vitamin A 1 is the predominant form in the mammalian serum and tissues [10,22,29,31] and would compete with vitamin A 2 and thereby reduce the red-shifting effect.In addition, high concentrations of exogenous vitamin A 2 could have unknown systemic effects on the organism because elevated levels of 3,4-didehydroretinoids have been documented in hyperkeratotic lesions and some skin neoplasms in humans [10].Overexpression of Cyp27c1 should also be tolerated by the immune system as orthologues can be found in most mammalian genomes, including the human genome [10].For instance, Johnson et al. [11] report localization of Cyp27c1 in the skin although the function of vitamin A 2 remains unclear.
Our experiments showed that Cyp27c1 is able to convert 0.4 μM vitamin A 1 present in Panserin 293A medium into vitamin A 2 , thereby red-shifting the spectral sensitivity of co-expressed ChR2 or ReaChR.This is in line with literature describing the catalytic efficiency of Cyp27c1 as one of the highest among animal cytochrome P450 family members [10] and a maximal catalytic efficiency at a vitamin A 1 concentrations between 0.1 and 2 μM.Because the levels of vitamin A 1 (all-trans-retinol) in human blood of 0.5-1.5 μM [22,29,31] are within this range, we conclude that Cyp27c1 overexpression should be effective for in vivo red-shifted optogenetics at physiological vitamin A 1 serum concentrations.Furthermore, our results show a higher redshifting effect by Cyp27c1 (ChR2: 10.5 nm and ReaChR: 14.3 nm) than by vitamin A 2 incubation (6.8 nm and 12.4 nm).This could be explained by a local intracellular production of vitamin A 2 close to the chromophore binding site at the time of opsin maturation when the chromophore is being incorporated.
The vitamin A 2 -induced red-shift has been shown for numerous opsins [27,28], corroborating the wide spectrum of possible applications of Cyp27c1 with vitamin A-based optogenetic actuators other than those we have tested.Sineshchekov et al. [28] predict the highest benefit by vitamin A 2 for rhodopsins with intrinsically long-wavelength absorption in which the additional red-shift by Cyp27c1 might significantly increase their efficiency and finally allow optogenetic activation in deep layers.We can support this notion because with ReaChR and Cyp27c1 we found halfmaximal photocurrents at 635 nm, approaching the therapeutic window of 650-900 nm.
In this study, we used high light intensities from a monochromator to determine the maximum possible plateau photocurrent.This required a large bandwidth of 30 nm and resulted in non-uniform intensities across the spectrum (Table 1).ChR2 plateau currents are almost fully saturated at the light intensities we have used [20], and ReaChR plateau photocurrents are saturated at 610 nm using ~ 2 mW/mm 2 [19].However, ReaChR could be not saturated for longer wavelengths which in turn would allow using higher light intensities to obtain larger photocurrents.
Potential applications of optogenetic tools in whole organisms with therapeutic purposes could be, among others, terminating ventricular tachycardia [5], seizure control in epilepsy [16], or restoring vision in patients with photoreceptor degeneration [26].All these could benefit from optogenetic proteins with spectral sensitivity in the red-light range, enabling better tissue penetration and the use of less energetic and therefore less damaging long-wavelength photons.Given the greater red-shift due to Cyp27c1 expression compared to vitamin A 2 incubation, we propose enzymatic vitamin A 2 production by Cyp27c1 in combination with long wavelength optogenetic actuators as a complementary strategy for red-shifted optogenetics.

Fig. 2
Fig. 2 Spectral sensitivity of ReaChR.a Expression of ReaChR in fusion to Cerulean (blue) in HEK 293 cells.b Representative ReaChR currents evoked by illumination (600 nm, 0.5 s, grey line) in ReaChR expressing HEK 293 cells in Panserin 293A medium supplemented with 25 μM vitamin A 1 (A1) or vitamin A 2 (A2) 24-48 h before experiments.c ReaChR steady-state photocurrent at different wavelengths in relation to the maximal current for each cell in

Fig. 4
Fig. 4 Cyp27c1 co-expression red-shifts the spectral sensitivity of ChR2 a Transient expression of ChR2-EYFP (yellow) in a HEK 293 cell line stably expressing Cyp27c1-EGFP (green).Special fluorescence filters were chosen to discriminate between EYFP and EGFP.b ChR2 photocurrents in relation to the maximal current for each cell in Panserin 293A medium for cells expressing Cyp27c1 without (CYP, n = 14) and with vitamin A 1 incubation (CYP + A1, 5 μM, n = 11) and in control cells without (CTR, n = 19) and with vitamin A 2 incubation (A2, 25 μM, n = 17).Note that Cyp27c1 expression shifts the spectral sensitivity of ChR2 at 50% photocurrent (black arrow).c Ratio of normalized ChR2 photocurrents in cells expressing Cyp27c1 and control cells shows up to three times higher currents at wavelengths between 550 and 600 nm.d Wavelengths resulting in 50% of ChR2 photocurrents from data shown in b calculated for each cell by linear fitting.e,f Quantification of normalized (e) and absolute (f) ChR2 photocurrents at 550 nm.. * p ≤ 0.05, ** p ≤ 0.01, **** p ≤ 0.0001

Fig. 5
Fig. 5 Cyp27c1 co-expression red-shifts spectral sensitivity of ReaChR a Transient expression of ReaChR-Cerulean (blue) in a HEK 293 cell line stably expressing Cyp27c1-EGFP (green).b ReaChR photocurrents in relation to the maximal current for each cell in Panserin 293A medium for cells expressing Cyp27c1 without (CYP, n = 15) and with vitamin A 1 incubation (CYP + A1, 5 μM, n = 14) and in control cells without (CTR, n = 15) and with vitamin A 2 incubation (A2, 25 μM, n = 14).Note that Cyp27c1 expression shifts the spectral sensitivity of ReaChR at 50% photocurrent (black arrow).c Ratio of normalized ReaChR photocurrents in cells expressing Cyp27c1 and control cells shows more than three times higher currents at wavelengths above 650 nm.d Wavelengths resulting in 50% of normalized ReaChR photocurrents from data shown in b calculated for each cell by linear fitting e,f Quantification of normalized (e) and absolute (f) ReaChR photocurrents at 650 nm from data shown in b. * p ≤ 0.05, ** p ≤ 0.01, **** p ≤ 0.0001