ISSN 0006-2979, Biochemistry (Moscow), 2023, Vol. 88, No. 10, pp. 1428-1437 © Pleiades Publishing, Ltd., 2023.
Published in Russian in Biokhimiya, 2023, Vol. 88, No. 10, pp. 1731-1741.
1428
Generation of Electric Potential Difference
by Chromatophores from Photosynthetic Bacteria
in the Presence of Trehalose under Continuous Illumination
Liya A. Vitukhnovskaya
1,2
, Andrei A. Zaspa
1
, and Mahir D. Mamedov
1,a
*
1
Belozersky Institute of Physical-Chemical Biology, Moscow State University,
119992 Moscow, Russia
2
Semenov Federal Research Center for Chemical Physics, Russian Academy of Sciences,
119991 Moscow, Russia
a
e-mail: mahirmamedov@yandex.ru
Received June 27, 2023
Revised July 20, 2023
Accepted August 26, 2023
Abstract— Measurement of electrical potential difference(Δψ) in membrane vesicles (chromatophores) from the purple
bacterium Rhodobacter sphaeroides associated with the surface of a nitrocellulose membrane filter(MF) impregnated with
a phospholipid solution in decane or immersed into it in the presence of exogenous mediators and disaccharide trehalose
demonstrated an increase in the amplitude and stabilization of the signal under continuous illumination. The mediators
were the ascorbate/N,N,N′N′-tetramethyl-p-phenylenediamine pair and ubiquinone-0 (electron donor and acceptor,
respectively). Although stabilization of photoelectric responses upon long-term continuous illumination was observed for
both variants of chromatophore immobilization, only the samples immersed into the MF retained the functional activity
of reaction centers(RCs) for a month when stored in the dark at room temperature, which might be due to the preserva-
tion of integrity of chromatophore proteins inside the MF pores. The stabilizing effect of the bioprotector trehalose could
be related to its effect on both the RC proteins and the phospholipid bilayer membrane. The results obtained will expand
current ideas on the use of semi-synthetic structures based on various intact photosynthetic systems capable of converting
solar energy into its electrochemical form.
DOI: 10.1134/S0006297923100024
Keywords: chromatophores, reaction center, cytochromebc
1
complex, membrane filter, semiconductor, continuous illumi-
nation, electrical potential
Abbreviations: Δψ,transmembrane electric potential difference; Asc,ascorbate; bc
1
,cytochromebc
1
complex; cyt,cytochrome;
ITO,indium-tin oxide semiconductor; MF,membrane filter; P
870
,chlorophyll dimer; Q
A
and Q
B
,primary and secondary qui-
none acceptors, respectively; RC, reaction center; TMPD,N,N,N’N’-tetramethyl-p-phenylenediamine; UQ
0
,2,3-dimethoxy- 5-
methyl-1,4-benzoquinone.
* To whom correspondence should be addressed.
INTRODUCTION
Over the past decades, multiple research efforts
have been focused on the development of highly effi-
cient artificial systems based on various dyes and semi-
conductors capable of converting light energy into elec-
tricity (see reviews [1,2]). However, such systems have
some disadvantages, such as high costs and the need
for expensive components, technical maintenance, and
disposal after a certain time. In view of this, one of the
promising approaches to the development of photoelec-
trochemical energy converters is the use of natural pho-
tosynthetic systems (see reviews [3,4]).
Vesicles formed by invagination of the intracyto-
plasmic membrane (chromatophores) of nonsulfur pur-
ple bacteria contain a photosynthetic apparatus ideally
suited for such studies. Unlike the thylakoid membranes
of cyanobacteria and chloroplasts, chromatophores of
GENERATION OF ELECTRICAL RESPONSE IN CHROMATOPHORES 1429
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
photosynthetic bacteria are the minimal structural and
functional units capable of using the energy of absorbed
photons for ATP synthesis [5]. Light-dependent cy-
clic electron transfer in chromatophores, for example,
in Rhodobactersphaeroides, occurs between the reaction
center(RC) and the cytochrome bc
1
complex with the
involvement of mobile membrane pool of ubiquinones
(UQ
10
) and endogenous soluble cytochrome (cyt)c
2
.
After RC excitation by a light quantum, the photo-
activated electron is transferred from the bacteriochlo-
rophyll P
870
dimer(P) to the primary(Q
A
) and then to
the secondary(Q
B
) quinone acceptors. Reduction of the
photooxidized P
870
occurs as a result of electron trans-
fer from the peripheral cyt c
2
(electron donor for RC).
According to the modified concept of the Q cycle (see
review [6]), oxidation of ubiquinol molecule formed in
the RC and transferred to the ubiquinol-oxidizing center
Q
o
of the bc
1
complex is organized in such a way that one
electron returns through the Rieske iron-sulfur protein
(Fe
2
S
2
) and cytochromesc
1
andc
2
(high-potential chain)
to the photooxidized P
870
and the other electron is trans-
ferred through the two-heme cytochromeb (low-poten-
tial chain) to the ubiquinone reductase center Q
i
for the
reduction of ubiquinone molecule from the ubiquinone
pool. Repeated initiation of the above reactions leads to
the formation of “extra” ubihydroquinone in the Q
i
site
and increase in the number of protons exiting into chro-
matophore lumens per absorbed photon. It should be
also noted that the light-induced vectorial transport of
charges in the RCs and cytbc
1
in the membrane vesicles
is associated with the generation of the transmembrane
electric potential difference (Δψ) [7-11], which is a pri-
mary form of energy storage.
A relatively simple procedure of chromatophore
preparation from bacterial cells, intact lipid environment
of energy-converting enzymes in chromatophores, abil-
ity of RCs to convert light energy with a high quantum
efficiency, and detailed knowledge of the mechanism
of Δψ generation in some parts of the electron trans-
port chain make chromatophores an attractive object for
photoelectrochemical studies. When using chromato-
phores in hybrid systems invitro, one of the important
steps is their immobilization on supports (conductors,
semiconductors, polymers, phospholipid membranes)
and measurement of the electric potentials [12-14] and/
or currents under continuous illumination [12, 15-19].
However, in the above-mentioned studies [12-14],
Δψ generation under long-term continuous illumination
has not been investigated. The current in the continu-
ously illuminated chromatophores in [15-19] was mea-
sured mainly with the three-electrode system with the
applied external electric field, so that the photocurrent
amplitude depended on the field magnitude.
In the present work, we studied generation of
electric potential difference in response to continuous
illumination in Rba. sphaeroides chromatophores im-
mobilized on the surface of a nitrocellulose membrane
filter(MF) impregnated with a solution of phospholipids
using direct electrometric method [13], which involves
Δψ registration using a pair of silver chloride (Ag/AgCl)
macroelectrodes immersed in an electrolyte solution
and connected to an operational amplifier. The ob-
tained results were compared with the electrometric data
for chromatophores immersed into the MF clamped on
both sides by semiconductor glass plates based on in-
dium-tin oxide (ITO) [20]. The obtained data clearly
demonstrated long-term retention of the stable photo-
electric activity of chromatophores in these system in
the presence of disaccharide trehalose.
MATERIALS AND METHODS
Cell cultivation and preparation of chromatophores.
Wild-type Rba.sphaeroides cells were grown under an-
aerobic conditions at 30°C in the Ormerod medium[21]
at a light intensity of 800 W·m
–2
. To obtain membrane
vesicles with a high content of endogenous soluble cyt c
2
,
we used the extraction procedure described in[22] with
minor modifications. Cells suspended in 25 mM Hepes-
NaOH (pH 7.5) containing several crystals of DNase
and protease inhibitors were disrupted with a French
press (Aminco, USA). After removing the pellet, the
supernatant was applied on a sucrose density gradient
(5-35%, wt/wt) and centrifuged in a vertical VTi-50 rotor
(acquired through the Moscow State University Develop-
ment Program) for 2 h at 27,000 rpm. The lower chro-
matophore band was collected, dialyzed twice against
25 mM Hepes-NaOH (pH 7.5) for 2 h, and concentrated.
Chromatophore suspension [~2 mg of bacteriochloro-
phyll (bChl) per ml] was frozen in liquid nitrogen and
stored at –70°C.
The concentration of bChl in chromatophores was
determined as described earlier [23]. Chromatophore ab-
sorption spectra were recorded with a Hitachi 3400 spec-
trophotometer.
Measurement of the electric potential difference in
chromatophores immobilized on the MF surface. Δψ was
measured using direct electrometric method developed
in our laboratory [13]. MF (Millipore, USA) with a pore
size of 0.22 μm and thickness of 150 μm was used as a
support for chromatophore immobilization. Circular
MF (diameter, 2.0 cm) impregnated with a solution of
azolectin (L-ɑ-lecithin, type II-S; Sigma) in decane
(80 mg/ml) was clamped between two compartments of
a collapsible Teflon cuvette so that the filter blocked an
opening (diameter, 0.4 cm) in the partition separating
the two compartments. Both compartments were filled
with 25 mM Hepes-NaOH (pH 7.5) containing 20 mM
MgCl
2
and chromatophores were added to one of the
compartments. After stirring for 1h, both compartments
were washed with a tenfold volume of the buffer without
VITUKHNOVSKAYA et al.1430
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
MgCl
2
using a peristaltic pump to remove magnesium
and unbound chromatophores.
Exogenous mediators were added before the mea-
surements to the cell compartment containing chro-
matophores immobilized on the MF surface.
Photoelectric responses were recorded using a pair
of silver chloride macroelectrodes (Ag/AgCl/3 M KCl)
immersed in the electrolyte solution on both sides of the
MF. The electrodes were connected to an operational
amplifier (Burr Brown 3554BM, USA); the latter was
connected to a Gage CS8012 analog-to-digital convert-
er (ADC) and a computer. An incandescent lamp with
a power of 90 W (12 V) was used as a constant light
source.
Measurement of the electric potential difference
in chromatophores immersed into the MF. The mea-
surements were performed in the ITO|chromatophores–
MF|ITO system. For this, 2.5 × 5 cm MF (pore diam-
eter, 0.22 μm; thickness, 150 μm; Millipore GSTF) was
placed on the surface of a glass slide coated with the ITO
semiconductor. Next, 30-40 μl of suspension of chro-
matophores with the bChl concentration of ~2 mg/ml
was applied dropwise to the MF surface (~1.0 cm
2
).
After adsorption for 10 min in the dark, the MF surface
was washed (2 × 250 μl) with 25 mM HEPES-NaOH
(pH 7.5) and then the second ITO electrode was placed
on the top.
It should be noted that in the ITO|chromato-
phores–MF|ITO system, the mediators had been added
to the chromatophore suspension before it was used for
the incorporation into MF.
Registration of electrical potentials in the ITO|chro-
matophores–MF|ITO system was carried out using
copper wires connected on one side to the glass slides
coated with ITO and to the operational amplifier on the
other side. The signal from the amplifier was fed to a
Gage CS8012 ADC connected to a computer. Saturating
continuous illumination was provided by an incandes-
cent lamp (12V, 90W).
Each photoelectricity measurement was repeat-
ed at least 3 times. The range of errors for the photo-
responses was ~5%. All measurements were carried out
at20±1°C.
The figures were prepared with the Origin7.5 soft-
ware package (OriginLab Corporation).
Optical spectroscopy. Photoinduced changes in the
absorbance at 603 nm, which reflect the redox proper-
ties of the primary electron donor P
870
, were recorded
with a single-beam differential spectrophotometer con-
structed in our laboratory. The measuring light from
a KGM-98 lamp passed through an HL-1 Jobin Ivon
monochromator (France), cuvette with a sample, glass
light filter, and second UM-2 monochromator, and
then hit a photomultiplier (PMT). The signal from the
PMT was fed through the operational amplifier to the
ADC (Gage CS8012) connected to the computer.
RESULTS
The aim of this work was to study Δψ generation
in intact bacterial membrane vesicles under continuous
illumination. Previously, it was shown [24] that chro-
matophores isolated under certain conditions (cell dis-
ruption with a French press at low ionic strength) from
the nonsulfur purple bacterium Rba. sphaeroides con-
tain ~70% cyt c
2
inside the vesicles (see “Materials and
Methods” section). In these chromatophores, reduction
of photooxidized P
870
in the RCs can occur as a result of
direct electron transfer from endogenous cytc
2
[24, 25].
In other words, functionally active chromatophores
should contain cyt c
2
, which along with a pool of ubi-
quinones, acts as a redox carrier between the RCs and
cyt bc
1
. The content of cyt c
2
was determined by record-
ing changes in the absorbance at 603 nm (which reflects
the redox properties of P
870
) in a suspension of chro-
matophores in response to single light flashes in theab-
sence and presence of 2% Triton X-100 (not shown)
(see[26]).
Figure1 shows Δψ generation under constant illu-
mination in Rba.sphaeroides chromatophores associated
with the surface of MF impregnated with a phospholip-
id solution. No photoelectric response was observed in
the absence of additives (mediators) (Fig. 1a, curve 1).
It should be noted that as in the case of a collodion film
[9, 10], association of chromatophores with MF impreg-
nated with a solution of phospholipids in decane re-
sults in the extraction of UQ both from the site of the
secondary quinone acceptor Q
B
in the RC protein and
the membrane pool. In addition, cytc
2
and the primary
electron donor bChl P
870
dimer are oxidized in the RC.
Under these conditions, light-induced electron transfer
in chromatophores is limited by the formation of the
P
+
870
Q
A
–
radical ion pair inside the RC protein. However,
charge transfer outside the RC in the described system
can be reconstructed by the saturation of immobilized
chromatophores with exogenous quinone and reduction
of endogenous cytc
2
(see[14]).
No photoelectric response was observed in chro-
matophores associated with the MF surface in the
presence of ascorbate (Asc) and N,N,N′N′-tetra-
methyl-p- phenylenediamine (TMPD) only in the as-
say medium (Fig. 1a, curve 2). The use of 2.5 mM
Asc/150 μM TMPD pair as an electron donor was need-
ed to reduce soluble cyt c
2
localized inside chromato-
phores, because of poor Asc penetration through the
membranes [9].
Figure 1a, curve 3 shows Δψ generation under con-
tinuous illumination in the presence of only 150 μM
2,3-dimethoxy-5-methyl-1,4-benzoquinone (UQ
0
,elec-
tron acceptor). The photoresponse amplitude under
these conditions was ~1.8 mV. UQ
0
is an efficient ex-
ogenous electron acceptor from quinones in the RCs
[27, 28] that is widely used in photoelectrochemical
GENERATION OF ELECTRICAL RESPONSE IN CHROMATOPHORES 1431
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
Fig. 1. a)Generation of electric potential difference under continuous illumination by chromatophores associated with the surface of MF (pore
size, 0.22μm; filter thickness, 150μm) impregnated with azolectin solution in decane (80 mg/ml) without additives (curve1), in the presence of
2.5mM ascorbate (Asc)/150μM N,N,N’N’-tetramethyl-p-phenylenediamine (TMPD) pair (curve2), and in the presence of 150μM UQ
0
only
(curve3). Incubation medium: 25mM HEPES-NaOH (pH7.5). Inset: photoresponse in the presence of 5mM Asc/150μM TMPD and 150μM
UQ
0
in the absence of chromatophores. Arrows(↑) and(↓) indicate light on and off, respectively. b)Generation of electric potential difference
in the medium containing 2.5mM Asc/150μM TMPD and 150μM UQ
0
in the absence (curve1) and presence (curve2) of 0.75M trehalose.
Fig. 2. Generation of electric potential difference under stationary illumination in the presence of 0.75M trehalose by associated with the MF sur-
face: a)chromatophores isolated by a standard method; b)chromatophores deficient in cytc
2
. Experimental conditions are as in Fig.1b, curve2.
systems [28]. No photoresponse was observed in the con-
trol samples containing Asc/TMPD and UQ
0
, but no
chromatophores (inset in Fig.1a).
Figure 1b, curve1 shows the photoelectric response
of chromatophores under continuous illumination in the
presence of both electron donor (Asc/TMPD) and ac-
ceptor (UQ
0
). It can be seen that only in the presence
of both mediators, a significant increase in the photo-
electric response was observed, followed by a two-com-
ponent decrease in Δψ with the fast (~3 s) and slow
(~180s) phases.
The following experiments were carried out to study
the effect of the disaccharide trehalose (bioprotector)
on the light-dependent formation of Δψ by chromato-
phores immobilized on the MF surface. In the presence
of Asc/TMPD and UQ
0
, addition of 0.75 M trehalose
VITUKHNOVSKAYA et al.1432
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
Fig. 3. a)Generation of electric potential difference in chromatophores associated with the surface of MF impregnated with a solution of phos-
pholipids. Conditions are as in Fig.1b (curve2) in the absence (curve1) and presence (curve2) of 5μM AntA; curve3, conditions are as in Fig.3a
(curve1) in the presence of 10μM atrazine. b)Generation of electric potential difference by chromatophores after 18h (curve1) and 40h (curve2)
of storage at room temperature. Experimental conditions are as in Fig.3a, curve1.
under continuous illumination stabilized Δψ for ~190 s
(Fig.1b, curve2). Under these conditions, stabilization
of Δψ signal was also observed under much longer illu-
mination (~1800s) (Fig.2a).
Figure 2b shows Δψ generation in the presence of
Asc/TMPD, UQ
0
, and trehalose by Rba. sphaeroides
chromatophores deficient in cytc
2
. Illumination of these
chromatophores led to the generation of electric poten-
tial difference with an amplitude of ~1.8mV, indicating
that the reduced 150 μM TMPD penetrating through
the membrane was unable to efficiently reduce photoo-
xidized P
870
under stationary conditions [11].
Charge transfer in the RC and bc
1
protein complex-
es in chromatophores is associated with the generation
of Δψ that can be measured by the electrochromic shift
of carotenoid absorption bands and direct electrometric
method [10]. Figure3a (curve1) shows Δψ generation
under continuous illumination in the presence of Asc/
TMPD, UQ
0
, and trehalose. To determine the contri-
bution of the bc
1
complex to the total photoresponse, an-
timycinA (AntA, inhibitor of the ubiquinone reductase
site Q
i
of the bc
1
complex) was added to the medium,
which reduced the photoresponse amplitude by ~12%
(Fig.3a curve2). The observed effect could be due to
the fact that UQ
0
binds to the Q
B
site in the RC [28] and
receives an electron from Q
A
–
; its reduced form (UQ
0
H
2
)
acts as a “substrate” only for a small fraction of the bc
1
complexes.
To prove that the observed photoelectric activity of
chromatophores was due to the functioning of RCs, atra-
zine (inhibitor of electron transfer between Q
A
–
andQ
B
)
was added to the medium. Indeed, addition of 10μM
atrazine almost completely inhibited generation of the
photoelectric response (Fig.3a, curve3), indicating that
in the studied system, electron transfer in the acceptor
site proceeded from the primary quinone Q
A
to the ex-
ogenous acceptor Q
0
.
To study the stability of photoresponses, chromato-
phores associated with the MF surface were stored in
the dark at room temperature and illuminated at regu-
lar intervals. The amplitude of Δψ, which was initially
~14 mV (Fig. 3a, curve 1), decreased to ~1.4 mV after
18 h of storage (Fig. 3b, curve 1). No photoresponse was
observed after 40h of storage (Fig.3b, curve2).
Figure 4 shows Δψ generation in chromatophores
immersed into MF and clamped on both sides by semi-
conductor indium-tin oxide glass plates (ITO|chromato-
phores–MF|ITO) in the presence of mediators (Asc/
TMPD, UQ
0
), antimycin A, and trehalose. It was as-
sumed that the redox mediators moved freely inside
the MF and could interact with the RCs and ITO elec-
trodes. When the system was illuminated for ~4000 s,
a stable nondecreasing photoelectric response with an
amplitude of ~30mV was generated [20].
It should be noted that the 18-h dark adaptation of
the ITO|chromatophores–MF|ITO system at room tem-
perature resulted in a significant decrease in the Δψ sig-
nal upon illumination for 180 s (not shown). The inset
in Fig. 4 shows Δψ generation upon addition of ~40 μl
of fresh 25 mM HEPES-NaOH (pH 7.5) containing
redox mediators (Ask/TMPD and UQ
0
) directly to the
ITO|chromatophores–MF|ITO system after its storage
GENERATION OF ELECTRICAL RESPONSE IN CHROMATOPHORES 1433
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
Fig. 4. Generation of Δψ in chromatophores immersed into MF (ITO|chromatophores–MF|ITO system) in the presence of 2.5mM Asc, 150μM
TMPD, 150μM UQ
0
, 0.75M trehalose, and 5μM AntA and illuminated for 4000s (control). Inset: Δψ generation after addition of fresh 25mM
HEPES-NaOH (pH7.5) containing Asc/TMPD and UQ
0
directly to the ITO|chromatophores–MF|ITO system on the day 30 of storage at room
temperature.
Fig. 5. Electron transfer pathways induced by stationary illumination in Rba.sphaeroides chromatophores associated with the MF surface(a)
andimmersed into MF(b).
for 30 days in the dark at room temperature. Under
these conditions, the photoresponse amplitude was
~70% of the control.
Figure 5 shows presumable electron transfer path-
ways in chromatophores immobilized by two different
methods.
DISCUSSION
The studies of the mechanism of Δψ generation in
chromatophores associated with the surface of a collo-
dion film impregnated with a lipid solution in response
to single light flashes using direct electrometric method
VITUKHNOVSKAYA et al.1434
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
demonstrated the presence of the following electrogen-
ic reactions: 1) charge separation between P
870
and Q
A
;
2) re-reduction of photooxidized P
870
by endogenous
cyt c
2
; 3) protonation of the doubly reduced secondary
quinone acceptor Q
B
(see review [11]); 4)electron and
proton transfer in the cytbc
1
complex [10].
The purpose of this work was to demonstrate Δψ
generation under stationary illumination of chromato-
phores immobilized on the surface of MF and immersed
into it and to study its mechanism.
It should be noted that adsorption of biomaterials
on a solid surface (Au, TiO
2
, ITO electrodes) can lead to
structural changes and emergence of electrostatic repul-
sion between the studied sample and the support surface
([29] and references therein). Taking into account the
biocompatibility, biodegradability, nontoxicity, and low
cost of porous nitrocellulose membrane filter [30, 31],
we used it as a matrix for chromatophore immobiliza-
tion. Interaction of chromatophores with the MF sur-
face was achieved by neutralization of negative charges of
the polar heads of chromatophore membrane phospho-
lipids and MF by addition of Mg
2+
or Ca
2+
cations [13]
(see “Materials and Methods” section).
To generate stable electric signals, we used func-
tionally active chromatophores with a high content of
endogenous cyt c
2
. Since the redox cofactors in the RC
and bc
1
transmembrane complexes are immersed deeply
in the protein matrix, the recording of Δψ under contin-
uous illumination invitro (in a semi-synthetic system)
was performed in the presence of exogenous mediators.
The Asc/TMPD pair was used because of the chromato-
phore membrane permeability for the reduced TMPD
and capability of this compound to reduce endogenous
cyt c
2
[9]. Soluble UQ
0
maintained the functional ac-
tivity of RCs by accepting electrons from the primary
quinone Q
A
–
in chromatophores associated with the MF
surface and from the secondary quinone Q
B
–
in the case
of chromatophores immersed into the MF [20,28]. UQ
0
was an efficient mediator between the quinone acceptor
site of the RC and electrodes [28,32].
In Rba. sphaeroides chromatophores associated with
the MF surface, loosely bound Q
B
and UQ molecules
was washed out with n-decane used as a hydrophobic
solvent for phospholipids during MF impregnation,
which resulted in the blockade of cyclic charge trans-
fer [13]. Under these conditions, ubihydroquinone
(UQ
0
H
2
) generated under stationary illumination could
not act as a substrate for the bc
1
complex, probably, be-
cause of its high hydrophilicity (Fig.5a).
On the other hand, when chromatophores were im-
mersed into MF, the functioning of the cyclic electron
transport chain with the participation of the RC and bc
1
complexes, UQ pool, and cytc
2
, was preserved. This was
confirmed by the fact that addition of AntA (bc
1
com-
plex inhibitor) led to a significant (almost twofold) in-
crease in the amplitude of the steady-state Δψ [20].
The increase in the amplitude of the photoelectric re-
sponse upon inhibition of the bc
1
complex was due to the
redirection of cyclic electron flow (which does not con-
tribute to the membrane potential in the studied system)
toward linear electron transfer between the ITO elec-
trodes and RCs (Fig.5b). This type of chromatophore
immobilization allowed to record stable non-decreasing
Δψ signal during prolonged illumination (~4000s) [20].
Therefore, the recorded maximal photoelectric re-
sponse was probably due to the light-induced direct
electron transfer along the cyt c
2
→ RC → Q
A
→ Q
0
→ O
2
path in the case of chromatophores associated with the
MF surface (Fig.5a) or ITO → cyt c
2
→ RC → Q
A
→ Q
B
→
→ UQ
0
→ ITO path for chromatophores immersed into
MF pores (Fig.5b). In other words, in both cases, gen-
eration of stationary Δψ was due to the operation of RCs
themselves. This was evidenced by the suppression of
electrical response generation in the presence of atra-
zine, an inhibitor of electron transfer between quinone
acceptors in RCs (Fig.3a, curve3).
In studies on the conversion of light energy, it is
important not only to obtain a significant amplitude of
electric current under continuous illumination, but also
to identify conditions for maintaining the functional ac-
tivity of samples during their long-term storage at room
temperature. In chromatophores associated with the MF
surface, an almost complete drop in the Δψ amplitude
was observed after 40 h of storage (Fig. 3b, curve 2).
The decrease in the photoresponse amplitude could be
associated either with a decrease in the resistance of
MF impregnated with a lipid solution [13] or with the
‘degradation’ of added mediators, in particular, Asc.
However, the recovery of the MF resistance (2 × 10
8
Om)
and addition of a fresh portion of the buffer contain-
ing mediators (Asc/TMPD, UQ
0
) to the assay medium
does not lead to recovery of Δψ (not shown). Therefore,
the decrease in the Δψ amplitude with time in the case
of chromatophores associated with the MF surface was
most likely associated with the conformational and struc-
tural changes in the RCs.
As for the stability of photoelectric responses of
chromatophores immersed into the MF, addition of a
fresh buffer with the electron donor and acceptor to the
ITO|chromatophores–MF|ITO system stored at room
temperature under aerobic conditions for 30 days, caused
a recovery of the Δψ amplitude to ~70% (inset in Fig.4)
relative to the control sample (Fig. 4), indicating that
the majority of chromatophores immobilized on the MF
remained functionally active for at least 30 days.
Hence, in both systems, stable maximal photore-
sponses were observed only in the presence of trehalose,
a disaccharide with unique physicochemical properties.
Previously, similar stable photoelectric responses were
detected in the presence of this osmolyte in isolated pig-
ment–protein complexes of PSI and PSII immersed into
MF [33, 34]. Note that trehalose also affects the nature
GENERATION OF ELECTRICAL RESPONSE IN CHROMATOPHORES 1435
BIOCHEMISTRY (Moscow) Vol. 88 No. 10 2023
of the electric response (Fig. 1b, curve 2), namely, sup-
presses the rapid burst and decay of Δψ at the start of
illumination (Fig. 1b, curve 1), which can be due to a
decrease in the ionic permeability of the chromatophore
membrane [35,36]. A similar effect of trehalose on the
photoresponse rapid burst and decay was observed in
chromatophores immersed into MF [20]. Stabilization
of photoresponses could be associated with an improve-
ment in the efficiency of interactions between the me-
diator(s) and proteins of the photosynthetic electron
transport chain. Preservation of a thin hydration shell
of transmembrane proteins in the presence of this disac-
charide can change their conformation into a conforma-
tion more optimal for their efficient functioning [37-39].
Trehalose might also stabilize lipid bilayers by replacing
water during formation of hydrogen bonds between its
hydroxyl groups and polar lipid heads [40]. In this case,
interactions of trehalose with the transmembrane pro-
teins and phospholipids in chromatophores can occur
only near the outer side of the membrane because of the
impermeability of chromatophore membrane for treha-
lose.
Therefore, trehalose stabilized photoelectric sig-
nals generated by both types of immobilized chromato-
phores; however, the most stable photoresponses were
observed when chromatophores were immersed into the
MF. This extremely simple method of sample immo-
bilization might help to preserve intact photosynthetic
proteins of chromatophore inside the MF pores at room
temperature for a long period of time.
The obtained results will expand modern ideas on
the use of semisynthetic structures based on various in-
tact photosynthetic systems (cyanobacteria and purple
bacteria cells [41], plant thylakoid membranes) capable
of converting solar energy into its electrochemical form.
Contributions. M.D.M. developed the concept and
supervised the study, analyzed electrical measurements,
and wrote the text of the article; L.A.V. and A.A.Z. iso-
lated bacterial membrane vesicles (chromatophores) and
performed electrical measurements.
Funding. The work was supported by the Russian
Science Foundation (project no.23-74-00025).
Ethics declarations. The authors declare no conflict
of interest in financial or any other sphere. This article
does not contain any studies with human participants
oranimals performed by any of the authors.
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