Implications for the impairment of the rapid channel closing of Proteomonas sulcata anion channelrhodopsin 1 at high Cl⁻ concentrations

Abstract

Natural anion channelrhodopsins (ACRs) have recently received increased attention because of their effectiveness in optogenetic manipulation for neuronal silencing. In this study, we focused on Proteomonas sulcata ACR1 (PsuACR1), which has rapid channel closing kinetics and a rapid recovery to the initial state of its anion channel function that is useful for rapid optogenetic control. To reveal the anion concentration dependency of the channel function, we investigated the photochemical properties of PsuACR1 using spectroscopic techniques. Recombinant PsuACR1 exhibited a Cl⁻ dependent spectral red-shift from 531 nm at 0.1 mM to 535 nm at 1000 mM, suggesting that it binds Cl⁻ in the initial state with a K_d of 5.5 mM. Flash-photolysis experiments revealed that the photocycle was significantly changed at high Cl⁻ concentrations, which led not only to suppression of the accumulation of the M-intermediate involved in the Cl⁻ non-conducting state but also to a drastic change in the equilibrium state of the other photo-intermediates. Because of this, the Cl⁻ conducting state is protracted by one order of magnitude, which implies an impairment of the rapid channel closing of PsuACR1 in the presence of high concentrations of Cl⁻.

Introduction

Microbial rhodopsins are photoreceptor proteins produced in diverse microbes, such as archaea, bacteria and eukaryotes. The molecular functions of microbial rhodopsins are also diverse, such as light-activated ion transporters (pumps and channels) and sensors. Despite such diversities, they commonly consist of a protein moiety having 7 α-helices spanning cell membranes and a chromophore (all-trans-retinal) that is covalently attached to a conserved Lys residue in the 7^th α-helix through a protonated Schiff base linkage^1,2. The chromophore is isomerized from an all-trans to a 13-cis configuration upon light irradiation in the time range of a few hundreds of femtoseconds, which induces sequential structural changes of the protein moiety in the time range of picoseconds to seconds. During those structural changes, several photo-intermediates are formed and then decay over time. Finally, the protein returns to its initial state. Therefore, such a light-induced reaction is cyclic and is called a photocycle. As a result, microbial rhodopsins exert individual functions during the photocycle².

One type of natural ion channel rhodopsins has recently become an intensive research target because of their remarkable effectiveness in optogenetic manipulation for neuronal silencing. Those proteins are called anion channelrhodopsins (ACRs), which passively transport monovalent anions, such as halide ions and NO₃^− 3,4. So far, three kinds of ACRs have been mainly investigated. ACRs from a marine cryptophyte alga Guillardia theta (abbreviated as GtACR1 and 2) are the first natural ACRs reported in 2015³. Several in vivo and in vitro investigations have revealed their optogenetic availability³, their channel gating mechanism during the photocycle^5,6,7, the roles of positively charged residues for anion conductance⁸, and their structure and structural changes around the chromophore^9,10. On the other hand, another homologous ACR from a marine cryptophyte alga Proteomonas sulcata (abbreviated as PsuACR1 or PsACR1) has also been investigated regarding its electrophysiological^4,11 and spectroscopic properties¹². Those studies have shown that GtACRs have the ability to work under weak light intensity and that PsuACR1 has rapid channel closing kinetics, rapid dark recovery of the peak photocurrent, and the most red-shifted absorption wavelength among the known ACRs. Those characteristics are beneficial for highly sensitive, precise and rapid optogenetic manipulations. Recently, other ACRs, named ZipACR and RapACR, have been reported to be more rapid than PsuACR1 and used for the optogenetics^13,14,15.

Previous investigations of the channel gating mechanism of GtACR1 and PsuACR1 have revealed the relationships between the photo-intermediates in the photocycle and the open and closed states of the channel^4,5,6,11,12. In these cases, the anion transport starts together with the formation of the L-intermediate, which is observed in the early stage of the photocycle, whereas it stops together with the formation of the M-intermediate. These relationships in ACRs are different from those in cation channelrhodopsins^16,17.

Focusing on the channel functions of ACRs in which several photo-intermediates are involved, anion concentration dependency, which is a useful parameter to characterize anion transport function, is still unclear. In anion pumping rhodopsins, such as archaeal and cyanobacterial halorhodopsins (HRs) and marine bacterial Cl⁻ pumping rhodopsins (ClRs), their anion transport mechanisms, including their anion binding ability, photocycle kinetics, sequence and timing of anion uptake and release, and residues important for anion transport, have been revealed based on the anion concentration dependency in their spectroscopic properties^{18,19,20,21,22,23,24,25,26}. Therefore, in this study we used static and time-resolved absorption spectroscopy to characterize the anion channel function of ACR with varying anion concentrations, especially for Cl⁻. We focused on PsuACR1 since it has rapid channel closing kinetics as described above, however the detailed mechanism involved is still unknown. PsuACR1 was expressed in and extracted from methylotrophic yeast Pichia pastoris cells as a recombinant protein in the presence of the detergent dodecyl-β-D-maltoside (DDM). These spectroscopic measurements revealed information about the Cl⁻ binding ability in the initial state and the Cl⁻ concentration-dependent changes of the photocycle that are directly connected to its anion channel function.

Results

Cl⁻ dependent absorption changes in the initial state

Retinal isomer composition analysis of PsuACR1 was performed using high performance liquid chromatography (abbreviated as HPLC). Figure 1A shows HPLC chromatograms of retinal oximes extracted from PsuACR1 under dark or light conditions. PsuACR1 showed slight dark and light adapted changes in its retinal isomer composition. With respect to the Cl⁻ concentration dependency on the retinal isomer composition, that dependency seemed to be larger in the presence of 1,000 mM Cl⁻ than in the presence of 0.1 mM Cl⁻, especially under the light condition. In summary, the chromophore composition in the initial state of PsuACR1 was predominantly the all-trans form, which facilitates the light-gated anion channel function, at more than 90% and 70% under dark and light conditions, respectively.

Figure 1

Photochemical properties of PsuACR1 in the initial state. (A) HPLC chromatograms of retinal oxime isomers extracted under dark (black lines) and under light (grey lines) conditions in the presence of 0.1 mM or 1,000 mM Cl⁻. The 4 peaks of the retinal oxime isomers were assigned as Ts (all-trans, 15-syn), Ta (all-trans, 15-anti), 13 s (13-cis, 15-syn) and 13a (13-cis, 15-anti). The molar content of all-trans retinal is described in the same panel. (B) Static UV-visible absorption spectra of PsuACR1 in the presence of 0.1, 1, 10, 100 or 1,000 mM NaCl. The directions of the Cl⁻ dependent spectral changes are indicated by arrows. (C) Hill plot of λ_max against the logarithm of Cl⁻ concentration (closed circles). The fitting curve is shown as a broken line. The fitting parameters for the Hill equation were as follows; A = 531 ± 0.207, B = 4.07 ± 0.250, K_d = 5.49 ± 1.62 and n = 1 (fixed).

To characterize the effect of Cl⁻ on the absorption properties of PsuACR1 in the initial state, we measured static UV-visible absorption spectra in varying Cl⁻ concentrations from 0.1 to 1,000 mM. As shown in Fig. 1B, the visible absorption maximum (abbreviated as λ_max) in the presence of 0.1 mM Cl⁻ was 531 nm. When the Cl⁻ concentration increased, the λ_max was red-shifted to 535 nm. At the same time, a minor absorption band at around 400 nm, a marker band for the deprotonated retinal Schiff base, disappeared. These results indicate that PsuACR1 binds Cl⁻ in the initial state and that the bound Cl⁻ increases the acid dissociation constant (pK_a) of the protonated retinal Schiff base. The same behavior was also observed for HRs^26,27. We then estimated the Cl⁻ binding affinity of PsuACR1 (the dissociation constant, K_d) from the Cl⁻ dependent shift of the λ_max. Figure 1C shows the Hill plot of λ_max against the Cl⁻ concentration, and from the Hill equation, the K_d was estimated to be 5.5 ± 1.6 mM.

Photocycle of PsuACR1 in the presence of 100 mM Cl⁻

The photocycle of PsuACR1 was investigated using time-resolved flash-photolysis in the time range of microseconds to seconds, during which the protein exerts its Cl⁻ channel function. Here we explain the photocycle overview in the presence of 100 mM Cl⁻ as an example. Figure 2A illustrates the flash-induced light-minus-dark difference absorption spectra from 10 μs to 1.4 s. After the flash excitation, the absorption for the initial state at 540 nm disappeared together with the concomitant appearance of three photo-intermediates with absorptions at 610 nm, 450 nm and 400 nm, tentatively assigned as K-, P₄₅₀- and M-intermediates (abbreviated as K, P₄₅₀ and M), respectively^6,12. Over time, these photo-intermediates increased and then decreased together with the recovery of the initial state and therefore the photocycle was completed.

Figure 2

Photocycle kinetics of PsuACR1 in the presence of 100 mM Cl⁻. (A) Flash-induced light minus dark difference absorption spectra. Red and blue lines represent the spectra at 10 μs and 1.4 s, respectively. The directions of the evolution of the spectral changes are indicated by arrows. (B) Absorption spectra of the P₁–P₄ states (red circles, orange triangles, green inverted triangles and blue diamonds, respectively) calculated from the fitting results. The spectrum of P₀ (grey broken line) represents the pure retinal spectrum. (C) Time evolution of flash-induced absorption changes (shown as grey dots) of the initial state (540 nm), K and P₆₀₀ (610 nm), L (500 nm), P₄₅₀ (450 nm) and M (400 nm), respectively. Fitting curves are shown as solid lines with colors. Time constants are shown in the same panel. (D) Photocycle scheme in the presence of 100 mM Cl⁻.

To examine the photocycle kinetics precisely, we performed global fitting analysis based on the sequential model^28,29. These data were successfully fitted by the exponential decay functions with the sum of 4 exponents, indicating that at least 4 kinetically defined states, P₁–P₄, were detected in our experimental time domain (Supplementary Fig. S1). Figure 2B shows the absorption spectra for the P₁–P₄ states calculated using the fitting results. P₀ represents the pure retinal spectrum of the initial state PsuACR1. From the spectra, we assigned two additional photo-intermediates with absorption peaks at 500 nm and 540 nm as the L- and ACR’-intermediates (abbreviated as L and ACR’), respectively, by reference to previous reports^{6,12,23,24,25}.

Figure 2C shows the time-dependent absorption changes of representative photo-intermediates as described above. Due to the time resolution of our flash-photolysis apparatus (10 μs), which is larger than that of a previous report by two orders of magnitude¹¹, the observed photocycle started from the equilibrium state between K (610 nm) and L (500 nm). The P₁ spectrum shown in Fig. 2B supports their equilibrium. In addition, the spectral shoulder corresponding to P₄₅₀ (450 nm) was observed in the P₁ state (Fig. 2A,B), indicating the co-existence with K and L. The P₁ state decayed to the P₂ state at the time constant τ₁ (0.219 ms, Fig. 2C). During this transition, the absorption at 610 nm transiently increased together with the decrease in the absorption at 500 nm. In a previous study, these transient absorption changes corresponded to the re-establishment of the K/L equilibrium in favor of K¹². However, based on the conventional photocycle scheme, it is more straight-forward to assign the transient increase in 610 nm as the generation of a new photo-intermediate rather than the re-establishment of the K/L equilibrium. Therefore, we adopted the P₆₀₀-intermediate (abbreviated as P₆₀₀), whose λ_max was estimated to be 600 nm from the P₂ spectrum in Fig. 2B, as an intermediate followed by L. Previous reports for PsuACR1 indicated the existence of an intermediate similar to P₆₀₀ named P₆₂₀¹¹ or K₂¹². In summary, an equilibrium state among P₄₅₀, L and P₆₀₀ was observed in the P₂ state (Fig. 2B). The P₂ state decayed to the P₃ state at the time constant τ₂ (21.3 ms, Fig. 2C). The P₃ state in the presence of 100 mM Cl⁻ contained L, P₆₀₀, and M (400 nm) at the same time (Fig. 2B). The P₃ state was then converted to the P₄ state at the time constant τ₃ (88.0 ms, Fig. 2C), where ACR’ (540 nm) mainly populated (Fig. 2B). Finally, the P₄ state decayed to the initial state P₀ at the time constant τ₄ (647 ms, Fig. 2C) to close the photocycle. From the analysis described here, we summarize the photocycle scheme of PsuACR1 in the presence of 100 mM Cl⁻ in Fig. 2D.

Cl⁻ dependence on the photocycle

The Cl⁻ dependence on the photocycle of PsuACR1 was also investigated by flash-photolysis. Figure 3 illustrates the light-minus-dark difference absorption spectra and the time dependent absorption changes of the representative photo-intermediates in the presence of 0.1–1,000 mM Cl⁻, except for 100 mM Cl⁻. From these results, two major effects of the Cl⁻ concentration on the photocycle were identified: (i) The accumulations of P₄₅₀ and M changed with increases in the Cl⁻ concentration (Figs 2A and 3A–D); and (ii) The lifetime of P₆₀₀ was prolonged and therefore its decay was synchronized with that of M in the presence of more than 1,000 mM Cl⁻ (Fig. 3H). The same effects were observed in the presence of 4,000 mM Cl⁻ (Supplementary Fig. S2).

Figure 3

The Cl⁻ dependence on the photocycle kinetics of PsuACR1 in the presence of (A,E) 0.1, (B,F) 1, (C,G) 10 and (D,H) 1,000 mM Cl⁻. (Left panels) Flash-induced light minus dark difference absorption spectra. Red and blue lines represent the spectra at 10 μs and 1.4 s, respectively. The directions of the evolution of the spectral changes are indicated by arrows. (Right panels) Time evolution of flash-induced absorption changes (shown as grey dots) of the initial state (540 nm), K and P₆₀₀ (610 nm), L (500 nm), P₄₅₀ (450 nm) and M (400 nm), respectively. Fitting curves are shown as solid lines with colors. Time constants are shown in the same panel.

To analyze the Cl⁻ dependence on the photocycle kinetics in detail, we compared the absorption spectra of the P₁–P₄ states at each Cl⁻ concentration (Fig. 4). From that analysis, we found that the Cl⁻ dependence changed at 10 mM Cl⁻. Therefore, we separately prepared the absorption spectra in the presence of 0.1–10 mM (panels A–D) and 10–1,000 mM (panels E–H). In the P₁ state, where K, P₄₅₀ and L were in equilibrium (Fig. 4A,E and I), the equilibrium shifted from L to K in the presence of 0.1–10 mM, whereas slight increases in L and P₄₅₀ were observed in the presence of 10–1,000 mM. Similarly, in the P₂ state, where P₄₅₀, L and P₆₀₀ were in equilibrium (Fig. 4B,F and J), the equilibrium shifted from L to P₆₀₀ in the presence of 0.1–10 mM Cl⁻, while increases in L and P₄₅₀ were observed in the presence of 10–1,000 mM Cl⁻. The spectra were significantly changed in the P₃ state (Fig. 4C,G and K). In the presence of 0.1–10 mM Cl⁻ (Fig. 4C,K), M and ACR’ accumulated and the equilibrium shifted from ACR’ to M. In addition, the spectrum in the presence of 10 mM Cl⁻ seemed to contain L and P₆₀₀ other than ACR’ at the same time (Fig. 4C,G), indicating there is a transition phase between the photocycle in the presence of lower or higher concentrations of Cl⁻. When increasing the Cl⁻ concentration from 10 to 1,000 mM (Fig. 4G,K), L and P₆₀₀ were clearly observed in the spectra. These intermediates were in equilibrium with M and the equilibrium shifted from M to L and P₆₀₀. Therefore, such a Cl⁻ dependent equilibrium shift resulted in an increase and a decrease in the accumulation of M and the prolongation of the lifetime of P₆₀₀, respectively, which was also supported by the results shown in Fig. 3H. In the P₄ state, where ACR’ mainly accumulated, absorption changes of ACR’ were detected (Fig. 4D,H and L), which reflects that Cl⁻ was taken up during the lifetime of ACR’.

Figure 4

The Cl⁻ dependence on the absorption spectra of the P₁–P₄ states (from the top to the bottom) in the presence of (A–D) 0.1–10 mM (red, orange and green, respectively) and (E–H) 10–1,000 mM Cl⁻ (green, blue and purple, respectively). The spectrum of P₀ (grey broken line) represents pure retinal spectra. The arrows indicate the direction of the changes in absorption and accumulation. For better understanding, the assignment and the equilibrium state of the photo-intermediates are shown in each panel. The Cl⁻ dependent equilibrium shift is indicated by the red arrow. (I–L) The photo-intermediates in the P₁–P₄ states are illustrated in the photocycle scheme of PsuACR1. The Cl⁻ conducting and non-conducting states are highlighted in red and blue, respectively.

Discussion

In this study, we investigated the Cl⁻ dependent changes in the photochemical properties of PsuACR1 using static and time-resolved spectroscopic techniques that revealed that the photocycle, which is directly connected to the anion channel function, is strongly affected by Cl⁻ concentration.

Indication for Cl⁻ binding in the initial state

We demonstrated that the visible absorption of PsuACR1 shifted with changes in the Cl⁻ concentration (Fig. 1B). In a previous study of PsuACR1, the λ_max in the absence or presence of Cl⁻ both resulted in 534 nm, which is close to our results in the presence of more than 100 mM Cl⁻ (Fig. 1C), and thus no spectral shift was observed¹². Currently, we cannot clearly explain why such a difference occurred. One possible reason may be that in the previous study more than a certain concentration (e.g. the K_d of 5.5 mM determined in this study) of Cl⁻ remained in the sample solution even after the buffer exchange. Incidentally, in the case of a homologous protein GtACR1, no spectral shift was observed between 0 and 300 mM Cl^− 6. The difference in the initial state Cl⁻ binding between PsuACR1 and GtACR1 will be an interesting issue.

PsuACR1 showed a Cl⁻ induced spectral red-shift (Fig. 1B), which is opposite to the case of many Cl⁻ pumping rhodopsins, such as the haloarchaeal Natronomonas pharaonis HR (NpHR)^18,22,23 and the bacterial Nonlabens marinus S1-08^T rhodopsin 3 (NM-R3)²⁵. On the other hand, spectral red-shifts similar to those of PsuACR1 were observed in haloarchaeal Halobacterium salinarum HR (HsHR)²⁰, in bacterial Mastigocladopsis repens HR (MrHR)³⁰ and in Salinibacter ruber sensory rhodopsin I (SrSRI)³¹. For the latter red-shifted species, two different Cl⁻ binding sites are hypothesized. One is in the vicinity of the protonated retinal Schiff base, which was revealed by crystal structure and spectroscopic measurements in HsHR³² and MrHR³⁰. To confirm this, we prepared a mutant of PsuACR1 for Ala93, which corresponds to Thr74 in MrHR, Thr126 in NpHR, and Asp85 in HsBR (Supplementary Fig. S3A). In the cases of MrHR and NpHR, amino acid substitutions at the 74^th and 126^th positions from Thr to acidic residues resulted in the disappearance of the spectral shift and thus the initial Cl⁻ binding ability^30,33. Therefore, we prepared the PsuACR1-A93E mutant with the hope of the same results obtained for the MrHR and NpHR mutants. Supplementary Fig. S3B shows the absorption spectra of PsuACR1-A93E in the presence of 0.1 mM or 1,000 mM Cl⁻. Unexpectedly, a Cl⁻ dependent spectral red-shift from 504 nm (0.1 mM) to 508 nm (1,000 mM) was observed. Therefore, it is unlikely that PsuACR1 shares the same Cl⁻ binding site with MrHR and NpHR in the initial state.

The other hypothesis about the initial Cl⁻ binding site is that it resides in the vicinity of the β-ionone ring of the retinal chromophore, which has been reported in SrSRI³¹. In this case, His131 near the β-ionone ring is involved in the Cl⁻ binding, where the bound Cl⁻ induces the delocalization of the positive charge on the protonated retinal Schiff base nitrogen towards the β-ionone ring that induces the spectral red-shift. To confirm this for PsuACR1, we found that His131 in SrSRI was substituted to Phe156 in PsuACR1 (Supplementary Fig. S3A). We further searched for other candidates having a positive charge, however such residues were not found near the β-ionone ring of the retinal in PsuACR1. Therefore, we successfully demonstrated the Cl⁻ binding ability of PsuACR1 in the initial state but identification of the specific binding site must await future study.

With regard to the Cl⁻ binding affinity, the K_d was estimated to be 5.5 ± 1.6 mM from the Hill equation (Fig. 1C), which was in the same order as HsHR (2.6 mM)³⁴, NpHR (5.0 mM)³⁵, bacterial Rubricoccus marinus HR (RmHR; 7.6 mM)²⁶ and MrHR (2.0 mM)³⁰. This result indicates that the natively expressed PsuACR1 in P. sulcata binds Cl⁻ in the initial state under physiological conditions (the Cl⁻ concentration in the marine environment is a few hundreds of millimolar).

Effects of Cl⁻ concentration on the channel function of PsuACR1: Relationships between photo-intermediates and Cl⁻ conducting and non-conducting states

Previous reports for GtACR1 and PsuACR1 described the photo-intermediates in the photocycle as corresponding to the anion-conducting and non-conducting states by combining spectroscopic and electrophysiological results^4,5,6,11,12. In those cases, the anion conductance starts and stops when forming the L and M photo-intermediates, respectively. Therefore, L and the following P₆₀₀ in our photocycle model are involved in the Cl⁻ conducting state and K, P₄₅₀, M and ACR’ are involved in the Cl⁻ non-conducting state (Fig. 4I–L).

We clearly observed a Cl⁻ dependent change of the photocycle kinetics, especially in the equilibrium states of the photo-intermediates in the presence of higher concentrations of Cl⁻ (10–1,000 mM, Figs 3 and 4). Notably, we identified the most drastic change in the P₃ spectra in the presence of a higher Cl⁻ concentration (Fig. 4C,G). The P₃ state in the presence of 100–1,000 mM Cl⁻ is considered to be the Cl⁻ conducting state due to the significant equilibrium shift from M to L and P₆₀₀ (Fig. 4G,K), whereas that in the presence of 0.1–1 mM Cl⁻ is considered to be the Cl⁻ non-conducting state due to the co-existence of M and PsuAR1’ in equilibrium (Fig. 4C,K). The P₃ spectrum in the presence of 10 mM Cl⁻ corresponds to the mixture of the Cl⁻ conducting and non-conducting states. Based on the relationships between the photo-intermediates and the Cl⁻ conducting and non-conducting states as described above, the P₁ and P₂ states correspond to the Cl⁻ conducting state, and the P₃ and P₄ states correspond to the non-conducting states in the presence of lower concentrations of Cl⁻ (see also Fig. 4I–L). On the other hand, in the presence of higher concentrations of Cl⁻ (e.g. 1,000 mM), the P₁–P₃ states correspond to the Cl⁻ conducting state, and the P₄ state corresponds to the non-conducting state (see also Fig. 4I–L). Figure 5A shows the time course for the generation and decay of the P₁–P₄ states. This result clearly indicates that the Cl⁻ conducting state is protracted by one order of magnitude in the presence of higher concentrations of Cl⁻. From these results, we hypothesize that one of the most pronounced characteristics of PsuACR1, i.e. the rapid channel closing and rapid dark recovery of the photocurrent^4,11, which enables the optogenetic neuronal silencing at rapid frequency, becomes impaired at higher concentrations of Cl⁻.

Figure 5

Cl⁻ concentration dependence of the photo-intermediates. (A) Time evolution of the kinetically defined states P₁–P₄ in the presence of lower (e.g. 10 mM, upper panel) and higher (e.g. 1,000 mM, lower panel) concentrations of Cl⁻. Cl⁻ conducting and non-conducting states of PsuACR1 are shown as red and blue lines, respectively. (B) The amount of M in the P₃ state (black) is plotted against the logarithm of the Cl⁻ concentration. The amount was calculated by subtracting the absorbance at 400 nm in the initial P₀ state from that in the P₃ state for M at each Cl⁻ concentration.

In addition, we noticed that the accumulation of M, which is involved in the Cl⁻ non-conducting state, changed in a Cl⁻ concentration-dependent manner, as shown in Fig. 5B. The accumulation of M first increased, then reached a maximum at 10 mM Cl⁻, and finally decreased with the increase in Cl⁻ concentration. From the Cl⁻ concentration dependency, we estimated that the Cl⁻ concentration for the first transition is close to the K_d value for the initial Cl⁻ binding (5.5 mM, Fig. 1C). On the other hand, the Cl⁻ concentration for the second transition was estimated to be several hundreds of millimolar. We suppose that in the presence of a higher Cl⁻ concentration than this value, a secondary Cl⁻ binding occurs in PsuACR1 that significantly inhibits the accumulation of M. Therefore, we propose that there is a causal relationship between the secondary Cl⁻ binding and the impairment of the rapid channel closing of PsuACR1 at higher concentrations of Cl⁻. Although the secondary Cl⁻ binding site has not been identified yet, we estimate that it is located near or along the Cl⁻ conducting pathway in the protein. Previously, the inhibitory role of the Arg residue on the extracellular surface of GtACR2, which is a candidate consisting of the Cl⁻ conducting pathway, for its anion channel function has been reported⁸. One of the authors’ discussion points regarding the inhibition mechanism is that the positively charged Arg84 interacts with the negatively charged Cl⁻, which prevents the Cl⁻ from being transported through the protein⁸. Together with the fact that PsuACR1 conserves the corresponding residue as Arg84, we estimate that the inhibitory role of Arg84 is related to the secondary Cl⁻ binding and therefore the Arg84 in PsuACR1 is one candidate for the secondary Cl⁻ binding site. If the secondary Cl⁻ binding occurs on the protein surface near Arg84, a mutation to destroy that secondary binding site would enable optogenetic silencing at a high frequency through PsuACR1 even in the presence of higher Cl⁻ concentrations. Another estimation is that water-filled cavities along the channel pathway in PsuACR1 contribute to the secondary Cl⁻ binding. X-ray and simulation structures of cation channelrhodopsins (CCRs) C1C2 and ChR2 from Chlamydomonas reinhardtii indicated that such cavities are distributed along the possible cation channel pathway and predicted to be involved in the cation permeation^36,37,38,39. Moreover, in the case of Cl⁻ conducting mutant of C1C2 (C1C2-E90K/R), the distribution of the cavities was expanded, which facilitated Cl⁻ distributed in the cavities and resulted in the increase in the affinity for Cl^− 40. In analogy with these CCRs, there should be similar water-filled cavities in ACRs including PsuACR1 to capture Cl⁻. We hypothesize that several Cl⁻ are captured by the cavity during the Cl⁻ conducting L- or P₆₀₀-intermediate in the presence of high concentrations of Cl⁻, which may stabilize the L or P₆₀₀ and thus remain the channel open.

The currently fastest ACR for optogenetic silencing, called ZipACR, originates from P. sulcata and thus is a homologous protein with PsuACR1 (identity 32%, similarity 71%)¹³. On the other hand, GtACR1 also shares a high sequential homology with PsuACR1 (identity 36%, similarity 74%). Based on our hypothesis, the similar Cl⁻ dependence and thus impairment of the channel closing in the presence of higher concentrations of Cl⁻ may occur in these homologous ACRs.

Conclusion

In this study, we analyzed the Cl⁻ dependent changes in the photochemical properties of PsuACR1 using static and time-resolved spectroscopic techniques. We found that PsuACR1 is able to bind Cl⁻ in the initial state at a K_d of 5.5 mM, which was estimated by the Cl⁻ dependent spectral red-shift. In addition, the Cl⁻ concentration dependency on the photocycle was clearly observed. In the presence of more than 10 mM Cl⁻, the photocycle of PsuACR1 was significantly changed as follows; (i) the accumulation of M, which is involved in the Cl⁻ non-conducting state, was strongly suppressed, and (ii) due to (i) and the drastic change in the equilibrium state of the other photo-intermediates, the Cl⁻ conducting state was protracted by one order of magnitude compared to that in the presence of lower concentrations of Cl⁻. These results suggest that the most pronounced characteristics of PsuACR1, rapid channel closing and rapid dark recovery of the photocurrent, which enables the rapid optogenetic manipulation for neuronal silencing, becomes impaired in the presence of high concentrations of Cl⁻. We propose that there is a causal relationship between the secondary Cl⁻ binding and the impairment of the rapid channel closing of PsuACR1 at high concentrations of Cl⁻. For the present use of ACRs for optogenetics, the proteins may not be exposed to such high anion concentrations condition in neurons. However, we hope that our study will be helpful to engineer optogenetic tools based on ACRs.

Methods

DNA construction of PsuACR1

The amino acid sequence of PsuACR1 was the same as previously reported (GenBank: KF992074.1, 291 residues)^4,11,12,41. For affinity purification, 8 histidine residues were attached to the C-terminus of PsuACR1 (abbreviated as PsuACR1_His₈). The gene encoding PsuACR1_His₈ with the codon optimization for Pichia pastoris was purchased from GENEWIZ (South Plainfield, NJ, USA). Two restriction enzyme sites, EcoRI and NotI, were attached to the 5′- and 3′-teminal ends of the PsuACR1_His₈ gene, and a stop codon was introduced before the NotI site. According to this, we obtained PsuACR1_His₈ having 299 residues in total. The gene and the expression vector pPICZ B (Thermo Fisher Scientific, Waltham, MA, USA) were digested by EcoRI and NotI restriction enzymes (Roche, Basel, Switzerland) and were then ligated using a Mighty Mix DNA ligation kit (Takara Bio Inc., Shiga, Japan). Nucleotide displacement was introduced using a QuikChange Site-Directed Mutagenesis kit (Agilent Technologies, Santa Clara, CA, USA) to produce PsuACR1-A93D and PsuACR1-A93E mutants. The nucleotide sequences were verified by the dideoxy sequencing method using a BigDye Terminator v1.1 Cycle Sequencing kit and a 3130 DNA Analyzer (Applied Biosystems, Foster City, CA, USA).

Protein expression and purification

The methylotrophic yeast Pichia pastoris SMD1168H strain (Thermo Fisher Scientific) was used as the protein expression host. For the transformation of P. pastoris, pPICZ B_PsuACR1_His₈ plasmid DNA was linearized using the PmeI restriction enzyme (New England Biolabs, Ipswich, MA, USA), purified using a FastGene Gel/PCR Extraction kit (NIPPON Genetics Co., Ltd, Tokyo, Japan), and then introduced to competent P. pastoris cells by a standard electroporation method. The transformed P. pastoris cells were inoculated and pre-cultured in BMGY medium containing 100 μg/mL Zeocin^TM (Thermo Fisher Scientific) for two days at 30 °C. The medium was exchanged to BMMY medium containing 0.5% methanol, 100 μg/mL Zeocin^TM and 10 μM all-trans-retinal (Sigma Aldrich, St. Louis, MO, USA), and protein expression was induced for 24 hr at 30 °C. After the protein induction, the cells were collected by centrifugation, resuspended in 50 mM Tris-HCl (pH 8.0) buffer containing 300 mM NaCl, and then sufficiently disrupted at 4 °C using a French press (100 MPa, repeated 6 times; Ohtake, Tokyo, Japan). The cell suspension was centrifuged at 7,000 rpm for 5 min at 4 °C (TOMY EX-136 equipped with a TLA-11 rotor; TOMY Seiko Co., Ltd., Tokyo, Japan) and the supernatant containing membrane fraction was collected. The membrane fraction was collected by ultracentrifugation at 40,000 rpm for 1 hr at 4 °C (Hitachi Koki CP 90NX equipped with a P70AT rotor; Hitachi Koki Co., Ltd., Tokyo, Japan). The procedures for solubilization with DDM (Dojindo Laboratories, Kumamoto, Japan) and affinity purification were the same as previously reported²⁵. For spectroscopic measurements, the buffer was sufficiently exchanged with 10 mM MOPS buffer (pH 7.0, Dojindo Laboratories) containing the desired concentrations of NaCl (0.1, 1, 10, 100 and 1,000 mM) and Na₂SO₄ (0, 300, 330, 333 and 333.3 mM) by centrifugation for 10 times (Amicon Ultra centrifuge filter, 30,000 molecular weight cut-off, Merck Millipore, Burlington, MA, USA) and gel-filtration chromatography (PD-10 column, GE Healthcare, Chicago, IL, USA). The ionic strength was kept at 1,000 mM by adding Na₂SO₄ because SO₄²⁻ is impermeable for PsuACR1⁴. For spectroscopic measurements at high salt concentrations, we prepared PsuACR1 samples in the same MOPS buffer containing 0.05% DDM and 4,000 mM NaCl or 1,333.3 mM Na₂SO₄. The ionic strength was kept at 4,000 mM. The same procedures were used to produce the PsuACR1-A93D and PsuACR1-A93E mutants. However, the PsuACR1-A93D mutant was not functionally expressed in the cells.

Retinal isomer composition analysis

Analysis of retinal isomer composition was carried out using a previously reported method³⁰. The retinal oxime extracted from Halobacterium salinarum bacteriorhodopsin (HsBR) in the purple membrane (PM) was used as a reference. For measurements under dark conditions, PsuACR1 and HsBR samples were kept in the dark for 1 week at 4 °C. For measurements under light conditions, the samples were respectively illuminated with green (530 nm) and orange (590 nm) LED light for 5 min before retinal oxime extraction. The concentrations of retinal oximes were calculated from peak areas of HPLC chromatograms.

Spectroscopic measurements

UV-visible absorption spectra were measured at 25 °C using a UV-1800 spectrophotometer (Shimadzu Corp., Kyoto, Japan). The protein concentration was adjusted to an optical density at 535 nm of 0.5–0.6. For the analysis of Cl⁻ concentration dependent spectral changes, the Hill equation was used to determine the Cl⁻ binding affinity in the initial state as follows:

$${\lambda }_{max}=A+B\times \frac{{[C{l}^{-}]}^{n}}{{{K}_{d}}^{n}+{[C{l}^{-}]}^{n}}$$

where A, B, [Cl⁻], K_d, and n represent the offset, the amplitude of λ_max change, the Cl⁻ concentration, the dissociation constant, and Hill coefficient, respectively.

Flash-photolysis experiments were carried out at 20 °C using a homemade system as reported previously^22,24. Data for time-dependent absorption changes from 380 nm to 700 nm every 10 nm were obtained. The number of data acquisitions was 30 for each wavelength. Data were analyzed by the sequential model as reported previously^28,29;

$${P}_{0}\to {P}_{1}\to {P}_{2}\to {P}_{3}\to {P}_{4}\to {P}_{0}$$

where P₀ and P₁–P₄ represent the initial state and the 1^st–4^th kinetically defined states, respectively. All data for the time-dependent absorption changes were simultaneously fitted with a sum of 4 exponential decay functions in this study. The number of exponents was determined by the reductions in the standard deviation of the residuals (Supplementary Fig. S1). In the P₁–P₄ states, physically defined photo-intermediates such as K, L, and M were populated at equilibrium. Details for the analysis are described in our previous reports^25,26,29.