ISSN 0006-2979, Biochemistry (Moscow), 2023, Vol. 88, No. 10, pp. 1571-1579 © Pleiades Publishing, Ltd., 2023.
Russian Text © The Author(s), 2023, published in Biokhimiya, 2023, Vol. 88, No. 10, pp. 1898-1907.
1571
Retinal-Based Anion Pump
from the Cyanobacterium Tolypothrix campylonemoides
Tatyana I. Rokitskaya
1,a
*, Aleksey A. Alekseev
2
, Fedor M. Tsybrov
2
, Sergej M. Bukhalovich
2
,
Yuri N. Antonenko
1,b
*, and Valentin I. Gordeliy
3,c
*
1
Belozersky Institute of Physico-Chemical Biology, Lomonosov Moscow State University, 119991 Moscow, Russia
2
Moscow Institute of Physics and Technology, 141701 Dolgoprudny, Moscow Region, Russia
3
Institut de Biologie Structurale (IBS), Université Grenoble Alpes, CEA, CNRS, Grenoble, France
a
e-mail: rokitskaya@belozersky.msu.ru
b
e-mail: antonen@belozersky.msu.ru
c
e-mail: valentin.gordeliy@gmail.com
Received June 30, 2023
Revised September 15, 2023
Accepted September 15, 2023
AbstractIn this work, TcaR rhodopsin from the cyanobacterium Tolypothrix campylonemoides was characterized. Analysis
of the amino acid sequence of TcaR revealed that this protein possesses a TSD motif that differs by only one amino acid
from the TSA motif of the known halorhodopsin chloride pump. The TcaR protein was expressed in E.coli, purified, and
incorporated into proteoliposomes and nanodiscs. Functional activity was measured by electric current generation through
the planar bilayer lipid membranes (BLMs) with proteoliposomes adsorbed on one side of the membrane surface, as well as
by fluorescence using the voltage-dependent dye oxonolVI. We have shown that TcaR rhodopsin functions as a powerful
anion pump. Our results show that the novel microbial anion transporter, TcaR, deserves deeper investigation and may be
of interest both for fundamental studies of membrane proteins and as a tool for optogenetics.
DOI: 10.1134/S0006297923100127
Keywords: microbial rhodopsin, photosensitive ion pump, optogenetics, proteoliposomes, bilayer lipid membrane
Abbreviations: BLM, planar bilayer lipid membrane; CCCP,carbonyl cyanide m-chlorophenyl hydrazone; PLs,proteoliposomes.
* To whom correspondence should be addressed.
INTRODUCTION
Microbial rhodopsins comprise a large family of
light-sensitive α-helical proteins with covalently bound
retinal as a cofactor. These proteins have been found in
microorganisms from all domains of life including vi-
ruses [1]. One of the main functions of these proteins is
their ability to perform light-driven transport of protons,
cations, and anions. The retinal-containing proteins
participate in energy storage by the marine microor-
ganisms, moreover, according to rough estimates, con-
tribution of the rhodopsin-based photosynthesis to the
total bioenergetics of biosphere is comparable or even
exceeds contribution of the chlorophyll-based photosyn-
thesis [2]. However, other functions of the proteins from
this family are known: sensory functions, ability to form
light-gated ion channels in the membrane[3], and even
regulation of enzymatic activity [4]. Structural-func-
tional studies of new microbial rhodopsins are very im-
portant for the development of new optogenetic tools[5].
Metagenomic analysis is often used for searching new
rhodopsins; and during the search for new objects a lot
of attention is paid to unusual pattern of the conserved
amino acid residues. The most studied light-driven pro-
ton pump, bacteriorhodopsin of Halobacterium sali-
narum, hasDTD motif (D85, T89, andD96– key ami-
no acid residues for proton transport)[6].
The gene encoding TcaR opsin have been found in
the course of bioinformatics search of the open metage-
nomic databases [7]. It has been located in the genome
of Tolypothrix campylonemoides VB511288 cyanobacte-
ria isolated from the green biofilm found on the façade
ROKITSKAYA et al.1572
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
of the building in the East-Indian city Santiniketan.
Analysis of the TcaR amino acid sequence reveals the
presence of the TSD motif. Rhodopsins from cyanobac-
teria with such motif have been characterized previously
[8-10], they have the ability to pump anions in bacterial
cells in response to illumination. The TSD motif differs
by only one amino acid from the motif of the known
chloride pump of the halorhodopsin, TSA[11].
In this study we present the data of functional stud-
ies of the TcaR rhodopsin using electrophysiological
[12, 13] and optical methods, including experiments on
determination of its ion selectivity in lipid vesicles and
nanodiscs. Electrophysiological approach used in our
study was developed by L. A. Drachev and A. D. Kaulen,
and later was widely applied for the investigation of rho-
dopsins in the modification suggested by Bambergetal.
[14-16]. The method is based on measuring of electric
photoresponses from the macroscopic planar bilayer
lipid membrane (BLM) with bound proteoliposomes
containing retinal proteins. This measuring approach
has been widely accepted due to the fact that it has high
sensitivity and, same as optical techniques, allows moni-
toring fast transient processes.
MATERIALS AND METHODS
Materials. Reagents from Sigma-Aldrich (USA)
were used in this work (unless indicated otherwise).
Proteoliposomes with TcaR rhodopsin. Nucleo-
tide sequence encoding TcaR (GenBank accession
no. JXC B00 000 000) was optimized for expression in
Escherichia coli cells using GeneArt software (Thermo
Fischer Scientific, USA). Nucleotide sequence at the
5′-end was optimized with the help of the RNA Web-
Server (Institute of Theoretical Chemistry, Vienna
University) with the goal to reduce the possibility of
hairpin formation at the RNA regions including ribo-
some binding sites. The gene was commercially synthe-
sized (Eurofins, Luxemburg) and cloned into an ex-
pression vector pET15b (Novagen, USA) at XbaI and
XhoI restriction sites. Hence, the gene was inserted in
front of the LEHHHHHH sequence (polyhistidine se-
quence used later for nickel-chelate affinity chromatog-
raphy). Expression in the cells of the E. coli C41(DE3)
strain and purification of the TcaR protein was car-
ried out according to the protocol described previ-
ously [17].
For preparation of proteoliposomes, a 1% (w/v)
solution of a soybean azolectin in chloroform (Sigma,
USA) was added to a glass flask. Chloroform was re-
moved with the help of a rotary evaporator and vacu-
um pump. The obtained thin lipid film formed on the
glass flask walls was resuspended in a solution contain-
ing 0.1 M NaCl (Applichem, Germany) and 2% (w/v)
sodium cholate to produce final concentration of azolec-
tin 1% (w/v). Lipid suspension was subjected to ultra-
sound treatment for 5 min at 4°C, followed by fast ad-
dition of a solubilized rhodopsin to final concentration
0.7 mg/ml and detergent-absorbing Bio-Beads SM-2
(Bio-Rad, USA). The obtained mixture was mixed in an
orbital shaker for 2h with minimal illumination, followed
by replacement of the beads (this procedure was repeat-
ed for at least four times).
Nanodiscs with TcaR. Assembly of nanodiscs and
incorporation of TcaR was carried out using standard
techniques described previously in the literature [18].
Dimyristoyl phosphatidylcholine (DMPC) (Avanti Po-
lar Lipids, USA) was used as a lipid. An elongated vari-
ant of the apolipoprotein-1 protein named MSP1E3D1
was used at a molar ratio DMPC/MSP1E3D1/
TcaR = 100/2/3. Dry lipid film obtained by dissolving
of DMPC powder in chloroform followed by evapora-
tion on a rotary evaporator (Heidolph, Germany) was
rehydrated by adding a detergent solution of 100 mM
CHAPS to obtain a lipid/detergent ratio of 1 : 2. Next,
a nanodisc-forming protein MSP1E3D1 was added to
the solution of the target protein TcaR solubilized in
micelles. The obtained mixture was incubated for 1 h at
room temperature, followed by addition of a BioBeads™
sorbent (Bio-Rad) in order to remove detergent at a ra-
tio of 1 g of the sorbent per 40 mg of detergent. Deter-
gent removal was carried out for 3h.
Planar bilayer lipid membrane was formed from
a decane solution, which contained 2% diphytanoyl
phosphatidylcholine and 0.04% (w/v) dimyristoyl ethyl-
phosphatidylcholine (Avanti Polar Lipids), on an aper-
ture in a partition separating a Teflon cell with a buffer
solution into two parts [19]. Diameter of the aperture
was 0.8 mm. Composition of a buffer solution varied and
is presented in figure captions. All experiments were
performed at room temperature (23-25°C).
Electric current was recorded under voltag-clamp
conditions. Potential difference was applied to silver
chloride electrodes connected through agar bridges into
the Teflon cell to both sides of the membrane. Current
was measured with the help of a patch-clamp amplifier
OES-2 (OPUS, Russia), digitized with a NI-DAQmx
(National Instruments, USA), and analyzed using a
commercial WinWCP Strathclyde Electrophysiology
Software, developed by J. Dempster (Strathclyde Uni-
versity, United Kingdom).
A halogen lamp Novaflex (World Precision Instru-
ments, USA) with power density 0.77W/cm
2
was used
for BLM illumination. The lamp illuminated the cell
from the front (cis) side, proteoliposomes were added to
BLM from the cis-side.
Proteoliposomes (PLs) with incorporated retinal
protein TcaR were added to the cis-side of the cell, which
was closer to illuminator. A high-ohmic electrode was in
the opposite part of the cell on the trans-side. Following
addition of 25-50 μl of TcaR-proteoliposomes to BLM
RETINAL-BASED ANION PUMP 1573
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
and 60-min incubation in a buffer solution containing
10 mM Mes and 10 mM Tris (pH ≈ 7), lipid membrane
was illuminated with a light in visible range of the spec-
trum. The BLM formed from the mixture of diphyta-
noyl phosphatidylcholine and cationic lipid dimyristoyl
ethyl-phosphatidylcholine has been previously shown to
facilitate adsorption of the negatively charged liposomes.
Significance of differences in data sets was evaluated
with the Student’s t-test.
Measurement of potential generation in suspension
of proteoliposome containing TcaR was carried out by
measuring fluorescence of the potential-sensitive dye ox-
onol VI (final concentration 2 μM) in a buffer containing
100 mM NaH
2
PO
4
and 1 M NaCl (pH 7.2) as described
previously [19]. Fluorescence intensity was re corded with
a Panorama Fluorat-02 spectrofluorimeter (Lumex, Rus-
sia), excitation wavelength 590nm and emission wave-
length 620 nm (slits– 5 nm) at 15°C. After reaching the
prescribed temperature 10-20 μl of proteoliposomes was
added to the cuvette, which was further illuminated with
a 1-mW green laser. To monitor generation of pH gra-
dient in the liposomes, fluorescence of pH-sensitive
dye, 9-aminoacridine (excitation– 425 nm, emission
455 nm) was used.
Absorption spectra of TcaR were recorded with a
Specord50 spectrophotometer (Analytik, Germany).
RESULTS AND DISCUSSION
According to the literature data, pump activity of
the retinal proteins is usually monitored using a simple
technique based on measuring changes of pH in a lipo-
some suspension with the help of a pH electrode, how-
ever, this method has low sensitivity and requires large
amounts of the protein. A more complicated method
exhibits a significantly higher sensitivity, in this method
proteoliposomes are attached to the surface of a planar
bilayer lipid membrane, but are not fused with it and re-
main intact on the BLM surface. It was shown that in
such system illumination induces generation of transient
electric potentials [12, 13] and transient currents across
the BLM[14-16], which could be recorded with regu-
lar macroscopic electrodes. Addition of protonophores
to such system usually results in the appearance of sta-
tionary photocurrents through the BLM, because the
electrical accessibility of the inner aqueous phase of the
proteoliposomes increases[16,20].
After the start of illumination, a small and fast
change of the BLM current towards negative values was
observed (black curve, Fig. 1,aandb), which was fol-
lowed by a return to the initial current values within a
second time scale. Further addition of a choline chloride
(Fig. 1a) or potassium fluoride (KF) (Fig. 1b) resulted
in the immediate increase of the transient current as a
response to switching illumination (light-gray curves),
as well as in continuous increase of the transient current
with time (dark-gray curves, recorded after 30 min).
The sign of the observed transient current for PL with
TcaR corresponds to the one for the PL with bacteri-
orhodopsin and indicates several possible ways of the
protein functioning: pumping of protons or monovalent
cations inside liposomes, pumping of monovalent an-
ions outside of liposomes, or some other possibilities.
Following the addition of tributyltin, which is a trans-
porter of monovalent anions [21, 22], to both sides of
the membrane resulted in the significant increase of
not only initial, but also of the stationary current as a
response to illumination (dotted curves). Addition of
another known anion transporter, prodigiosin [23], in-
stead of tributyltin, also resulted in the increase of initial
transient and stationary BLM photocurrents (Fig. 1c).
The results of experiments with the adsorbed PL on the
effects of addition of 50 mM chloride ions followed by
addition of 1 μg/ml of tributyltin on the amplitude of
the initial photoresponse of BLM (4 experiments) are
presented in Fig. 2. Initial photocurrent in the presence
of 50 mM of chloride anion was taken as one unit. It can
be seen that the addition of chloride ions causes increase
of the initial current (p < 0.0003), and the following ad-
dition of anion transporters leads to the current increase
(p<0.006).
When an experiment was conducted in the medi-
um with sulfate anion as a main anion in the electro-
lyte [medium composition: 10 mM Mes, 10 mM Tris, and
100 mM Na
2
SO
4
(pH 7.0)], prolonged incubation of li-
posomes with the BLM also resulted in their adsorp-
tion on the surface of the planar lipid membrane, which
was manifested by the appearance of a transient current
on illumination (Fig. 3, black curve). However, in this
case the amplitude of the transient current was low-
er in comparison to the one observed in the presence
of chloride anion. Addition of protonophore (carbonyl
cyanide m-chlorophenyl hydrazone, CCCP) increased
the stationary current upon illumination (light-gray
curve), and following addition of 60mM sodium chlo-
ride (dark-gray curve) resulted in significant increase
in the initial current induced in response to the illumi-
nation. Prodigiosin added at the end of the experiment
significantly increased the stationary BLM photocurrent
(Fig.3, dotted curve).
In all experiments with adsorption of proteolipo-
somes on BLM, addition of potassium chloride, sodi-
um chloride, choline chloride, or potassium fluoride, as
well as addition of the transporters of monovalent anions
(tributyltin and prodigiosin) resulted in the significant
increase of the transient photocurrent. However, small
transient photocurrents were observed after attachment
of liposomes on the planar lipid membranes even in the
absence of monovalent anions. It is likely related to the
presence of chloride anions inside liposomes and their
leakage from the electrodes’ agar bridges to the solution.
ROKITSKAYA et al.1574
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
Fig. 1. Measurements of electrical current through BLM with adsorbed proteoliposomes containing TcaR at BLM potential 0mV. Period of mem-
brane illumination is shown with solid black line. a)BLM current during incubation with liposomes (50μl) for 60min (black curve); light-gray
curve– BLM current immediately after addition of 50mM choline chloride; dark-gray curve– after 30-min incubation with choline chloride;
dotted curve– after addition of 1μg/ml of tributyltin. b)BLM current during incubation with liposomes (25μl) for 60min (black curve); light-
gray curve– BLM current immediately after addition of 50mM KF; dark-gray curve– after 30-min incubation with KF; dotted curve– after ad-
dition of 1μg/ml of tributyltin. c)BLM current during incubation with liposomes (25μl) for 60min (black curve); BLM current immediately after
addition of 50mM choline chloride; dark-gray curve– after 30-min incubation with choline chloride; dotted curve– after addition of 150nM
of prodigiosin. Buffer solution contained 10mM Mes and 10mM Tris(pH7.0).
RETINAL-BASED ANION PUMP 1575
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
Fig. 2. Summarized results of four experiments with TcaR-proteoli-
posomes investigating effect of addition of 50 mM chloride ions and
following addition of 1 μg/ml of tributyltin on amplitude of the initial
BLM photoresponse. Initial photocurrent in the presence of 50 mM
of chloride anion was taken as one unit.
Fig. 3. Electric current in BLM with adsorbed proteoliposome contain-
ing TcaR in the medium containing 100mM Na
2
SO
4
. Period of mem-
brane illumination with white light is shown by solid black line. BLM
current during incubation with liposomes (25μl) for 120min (black
curve); light-gray curve– BLM current after addition of 2μMCCCP;
dark-gray curve – after addition of 60 mM NaCl; dotted curve
after addition of 150 nM prodigiosin. Buffer contained 10 mM Mes,
10mM Tris, and 100 mMNa
2
SO
4
(pH7.0).
We prepared membrane nanodiscs with incorporated
TcaR protein and measured photoresponses of BLM in
their presence in different media. Nanodiscs does not
have inner space filled with water, hence, the equivalent
electric scheme in this case could differ from the exper-
iments with liposomes. The results of measuring BLM
photocurrent in the buffer with 100 mM NaCl (Fig. 4a),
100 mM Na
2
SO
4
(Fig. 4b), and 100 mM potassium glu-
conate (Fig. 4c) after addition of 10 μl of nanodiscs
at the cis-side of BLM are presented in Fig. 4. Nano-
discs rapidly adsorbed on the BLM, and already after
20 min BLM currents appeared in response to illumi-
nation. It is clearly seen that the significant transient
currents were observed only in the case of the medium
with sodium chloride (Fig. 4a; light-gray curve). In the
presence of sodium sulfate or potassium gluconate the
observed photocurrents were significantly lower (light-
gray curves in Figs. 4,bandc). Moreover, in the case
of 100 mM Na
2
SO
4
(Fig. 4b) the first rapid response
has even opposite sign. Addition of sodium chloride at
the end of each experiment resulted in appearance of a
large immediate current change in response to illumina-
tion (Fig. 4, b and c; dark-gray curves), or further in-
crease of the initial current (Fig. 4a). This result allows
us suggesting that sodium, potassium, sulfate, and glu-
conate ions are not transported by the pump. The sta-
tionary BLM photocurrent increased significantly in the
presence of CCCP protonophore or anion transporter
tributyltin (medium-gray and dotted curves in Fig. 5).
In conclusion these experiments indicate the ability of
the retinal-containing protein TcaR to transport chloride
anions across the membrane in response to illumination.
The data presented in Fig.1b allow us suggesting the
ability of the TcaR protein to transport fluoride anions.
Transport of hydroxyl anion by this protein also cannot
be excluded. It was shown previously that the mem-
brane fragments with halorhodopsin that has similar se-
quence of important amino acids (the TSA motif) could
generate photocurrent in the presence Cl
, Br
, and
I
, but not in the presence of SO
4
2–
, F
, and NO
3
[24].
However, depending on the illumination conditions ha-
lorhodopsin could function as a light-driven chloride
pump or proton pump [25]. According to our results,
transport of anions by the TcaR exposed to light is re-
alized from inside of the liposomes to outside (which
is equivalent to the transport into the cell cytoplasm).
Hence, a direction of the active transport of anions by
the TcaR and halorhodopsin is the same.
It was shown previously that the fluorescent dyes
such as potential-sensitive oxonolVI and ΔpH-sensitive
9-acridine amine(9-AA) could be used for measuring ac-
tivity of the rhodopsins in suspension [19,26]. Typical re-
sponse of oxonolVI fluorescence on addition to the sus-
pension of proteoliposomes containing TcaR is presented
in Fig.5a. Significant decrease of the fluorescence signal
is observed during illumination with green light, which
suggests generation of membrane potential on the lipo-
somes. OxonolVI is an anionic dye and decrease of its
fluorescence indicates generation of potential with plus
sign inside the liposomes, which corresponds to the same
polarity as in the similar experiments with bacteriorho-
dopsin[26]. It should be mentioned that the sensitivity
of this method is significantly lower that of the meth-
od based on the measurement of photocurrent on BLM
[19], hence, generation of large fluorescence responses
ROKITSKAYA et al.1576
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
Fig. 4. Time-dependencies of electric current in BLM with adsorbed nanodiscs containing TcaR at BLM potential 0mV. Period of the membrane
illumination with white light is shown with solid black line. a)BLM current during incubation with nanodiscs (10μl) for 5min (black curve);
light-gray curve– after 20-min incubation with nanodiscs; medium-gray curve– after addition of 2μM of CCCP; dotted line– after addition of
1μg/ml tributyltin; dark-gray curve– after addition of NaCl (to concentration 200mM). Buffer solution contained 10mM Mes, 10mM Tris, and
100mMNaCl(pH7.0). b)Similar current time-dependencies in buffer solution containing10mM Mes, 10mM Tris, 100mM Na
2
SO
4
(pH7.0).
c)Similar current time-dependencies in buffer solution 10mM Mes, 10mM Tris, 100mM potassium gluconate (pH7.0).
RETINAL-BASED ANION PUMP 1577
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
Fig. 5. Ion-transporting properties of TcaR in proteoliposome suspen-
sion measured by changes of fluorescence of 2 μM oxonolVI(a) and
4 μM 9-amino acridine(b). 10μl of proteoliposomes were suspend-
ed in 1 ml of medium containing 1 M NaCl and 100 mM NaH
2
PO
4
(pH7.2). Period of membrane illumination with the light of green LED
is shown with solid black line.
Fig. 6. Absorption spectra of TcaR in nanodiscs in the presence of
varying concentration of potassium chloride. Measurement medium
contained 10mM Mes and 10mM Tris (pH6.5). Potassium chloride
concentrations: 0mM (black line), 10mM (light-gray line), 50mM
(dark-gray line), and 150mM (dashed line).
in the suspension of proteoliposomes withTcaR (Fig.5a)
indicates high efficiency of the TcaR pump. Similar ex-
periments using the 9-AA dye demonstrated that no pH
gradient is formed in this system (Fig.5b).
A series of absorption spectra of TcaR in the ab-
sence of chloride anions (black curve) and in the pres-
ence of increasing concentrations of chloride anions
(gray and dotted curves) is presented in Fig.6. Position
of absorption maximum of the TcaR protein in nano-
discs is at 531 nm, and a 5-nm shift of the absorption
maximum towards short wavelength occurs after addi-
tion of 50-150mM of chloride ions. Furthermore, opti-
cal density at the absorption maximum increased. These
data are in good agreement with the effect of chloride
anions on the absorption spectra of halorhodopsin in-
vestigated previously [8, 9, 27] and provide support to
the notion that TcaR is an effective chloride pump.
Analysis of amino acid sequence of TcaR and re-
sults obtained in this study allow us suggesting that
TcaR exhibits functional similarity with halorhodopsin.
Halorhodopsin participates in maintenance of salt bal-
ance in bacteria, and, it could be assumed, that physi-
ological role of TcaR in cyanobacteria is similar. Con-
sidering that halorhodopsin is used in optogenetics,
TcaR could also find its application niche among the
used optogenetic tools. It seems that the TcaR protein
deserves more detailed and comprehensive investigation
including investigation of peculiarities of its photocycle,
as well as its structure.
Contributions. V.I.G. concept of the study; A.A.A.,
T.I.R., Y.N.A., S.M.B., F.M.Ts. conducting experi-
ments; Y.N.A., V.I.G., T.I.R. writing text of the paper.
All authors participated in discussion of the obtained re-
sults and editing of the final text of the paper.
Funding. This work was financially supported by
the Russian Science Foundation (grants 23-24-00038,
21-64-00018) and by the Ministry of Science and
Higher Education of the Russian Federation (project
AAAA-A19-119031390114-5).
Ethics declarations. The authors declare no conflict
of interests in financial or any other sphere. This article
does not contain any studies with human participants
or animals performed by any of the authors.
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