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J Biol Chem, Vol. 274, Issue 33, 23535-23540, August 13, 1999
From the Protein Engineering Laboratory, Biotechnology Centre,
Indian Institute of Technology, Powai, Mumbai 400 076, India
Factors regulating retinal biosynthesis in
halobacteria are not clearly understood. In halobacteria, events
leading to the biosynthesis of bacteriorhodopsin have been proposed to
participate in stringent regulation of retinal biosynthesis. The
present study describes a novel approach of in vivo
introductions of mRNA and membrane proteins via liposome fusion to
test their role in cellular metabolism. Both the bacterioopsin-encoding
mRNA and the liposome-encapsulated bacterioopsin (apoprotein) are
independently introduced in spheroplasts of the purple
membrane-negative strain Halobacterium salinarium that
initially contain neither bacterioopsin nor retinal. Isoprenoid analyses of these cells indicate that the expression/presence of
bacterioopsin triggers retinal biosynthesis from lycopene, and its
subsequent binding to opsin generates bacteriorhodopsin. When
bacteriorhodopsin and excess retinal were independently introduced into
spheroplasts of purple membrane-negative cells, the introduction of
bacteriorhodopsin resulted in an accumulation of lycopene, indicating
an inhibition of retinal biosynthesis. These results provide direct
evidence that the formation of bacterioopsin acts as a trigger for
lycopene conversion to The study of light-activated retinal proteins (1) provides us with
information on how organisms adapt to their environments using light.
One such organism that has attracted scientific attention is
Halobacterium salinarium. This organism contains three
unique retinal proteins that control diverse functions: (a)
bacteriorhodopsin involved in light-induced energy transduction (2, 3),
(b) sensory rhodopsin controlling light-induced movement
(4), and (c) halorhodopsin involved in light-induced
chloride transport (5). Retinal acts as a chromophore and is essential
for the light-induced activity of these retinal proteins. In the case of bacteriorhodopsin (bR),1
the apoprotein bacterioopsin (bOp) is attached to
all-trans-retinal via the Lys-216 residue to form the
chromoprotein bR (6).
In halobacteria, intermediates in the pathway of retinal biosynthesis
are well characterized, and its final biosynthetic stages are known to
involve the cyclization of lycopene to In this study, we report a new approach to understand the regulating
factors involved in retinal biosynthesis in halobacteria. In
particular, this approach involves the in vivo introduction of mRNA or membrane proteins via liposome fusion into halobacterial spheroplasts. Three potential regulatory elements, bop
mRNA (the transcriptional product of the bop gene), bOp
(the translational product), and bR (the final refolded protein), were
independently introduced into spheroplasts of purple membrane-negative
(Pum Materials--
Synthetic oligonucleotides were custom
synthesized from Genetech Associates (Mumbai, India). Restriction
enzymes and other enzymes such as T7 RNA polymerase were purchased from
Bangalore Genei (Bangalore, India). Other chemicals were obtained from
Sigma. N-NBD-PE and N-Rh-PE were obtained from
Molecular Probes. 1,2-Dimyristoyl-glycero-3-phosphocholine, and CHAPS
were purchased from Fluka Inc. (Buchs, Switzerland). Lipofectin
was purchased from Life Technologies, Inc. Bacto yeast extract and
Bacto-tryptone were obtained from Difco. all-trans-Retinal was a kind gift from Dr. A. K. Singh (Chemistry Department, Indian Institute of Technology, Bombay, Mumbai, India).
Pum Construction of pGEM-SBOP-L+ and
pGEM-SBOP-L In Vitro Run Off Transcription--
Both plasmids
pGEM-SBOP-L+ and pGEM-SBOP-L Lipofection of Spheroplasts Using bop
mRNA--
Lipofectin-complexed bop mRNA
(Lipofectin:mRNA ratio, 2.5:1) was prepared as described previously
(14) and mixed with a suspension of spheroplast cells (3:5 (v/v); see
below). The mixture was incubated at 37 °C for 45 min.
E. coli Expression of Bacterioopsin--
Bacterioopsin samples
with and without the leader peptide sequence were isolated and purified
after isopropyl-1-thio- Preparation of bOp- and bR-containing Liposomes--
bOp- and
bR-containing liposomes were prepared using sonication (16, 17). A
chloroform/methanol solution containing 2 mg of egg phosphatidylcholine
and 18 mg of acetone-ether-washed halobacterial lipids (18) was dried
under N2 gas, lyophilized, and dispersed into 0.5 ml of 40 mM HEPES-KOH, pH 7.0, and 100 mM KCl. The lipid
suspension was then diluted with an equal volume of distilled water
containing 76.8 nmol of bR or bOp and sonicated (cycles of 15-s
sonication and 45-s rest) at 4 °C for 20 min under N2
gas. The proton pumping activity of bR proteoliposomes was measured as
described previously (19). Both bOp (after regeneration by the addition
of all-trans-retinal) and bR were incorporated predominantly
in an inside-out direction because light-induced alkalinization of bulk
medium was observed (data not shown).
Cell Growth and Preparation of Spheroplasts--
Cell growth and
spheroplast preparation were carried out essentially as described by
Seehra and Khorana (20). Both Pum+ and Pum Fusion of bOp- and bR-containing Proteoliposomes with
Spheroplasts of Pum Protein Expression and Isolation--
After liposome fusions and
the appropriate incubations, spheroplast solutions were washed with
basal salts containing 0.1 M MgCl2, and the
cells were suspended in growth medium containing peptone (the volume
was the same as that used during the original growth). The cells were
grown for 12 h, harvested by centrifugation (20,000 × g for 30 min), and washed with 4 M NaCl. For
anaerobic growth, cells were grown on 0.5% arginine and in the
presence of nitrogen as described previously (21). The pelleted cells were lysed by suspension in distilled water, and the membranous fraction was collected by centrifugation at 30,000 × g
for 30 min and washed three times with distilled water (20 ml). Samples were removed and subjected to SDS-PAGE. After the final wash, the
pellet was layered on a 15-65% (w/v) sucrose density gradient (25 ml)
and centrifuged at 150,000 × g for 16 h (23). The
purple band of bR was isolated and washed four times with distilled
water (25 ml) to remove sucrose. Bacteriorhodopsin obtained in this manner was characterized using UV-visible spectroscopy and SDS-PAGE. For electrophoresis, equal amounts of cells were lysed with water, and
aliquots were separated by electrophoresis using 15% SDS-PAGE.
Isolation of Isoprenoids from Spheroplasts--
Isoprenoids were
isolated from H. salinarium cells as described previously
(24). Spheroplasts grown in a 100-ml volume were lysed in 1 ml of water
and treated with DNase. Under vigorous stirring, the lysate was added
into 9 ml of acetone. After 20 min in the dark, 4 ml of
n-hexane and 1 ml of water were added. The upper phase
containing the pigments was evaporated under a vacuum, and the pigments
were diluted in 100 µl of toluene. The sample was applied to an
Alumina column (16 g; activity grade II). The elution of Overall Strategy--
A threefold experimental strategy has been
used in this study: (a) to see whether the presence of bOp
acts as a trigger for retinal biosynthesis, bop mRNA was
introduced using lipofection and subsequently translated into a
Pum Spheroplasts of Pum Liposome-mediated Introduction of bop mRNA into Spheroplasts of
Pum
It has been shown that spheroplasts are incapable of processing
immature bR, and only when they are returned to normal cells can they
process bR to cleave off the leader sequence (20). Fig. 2B
shows the presence of unprocessed bR in spheroplasts of Pum bOp and bR Can Be Introduced in Vivo into Membranes of Spheroplasts
of H. salinarium--
The fusion of proteoliposomes containing bOp and
bR was done with spheroplasts of the Pum
The liposome fusion process was monitored using FRET. Fluorescent
donor-labeled lipids and acceptor-labeled lipids (N-NBD-PE and N-Rh-PE; see "Experimental Procedures") were
incorporated into liposomes and fused with spheroplasts. In the case of
proteoliposomes containing bR, the fluorescence of N-NBD-PE
is quenched by bR due to its strong absorption at 560 nm. FRET analysis
was performed, and the results indicated that over a period of 1 h, the fluorescence intensity increased as the donor- and
acceptor-labeled lipid/bR molecules move away from each other within
the membrane as a result of fusion. As a result, a decrease in the
quenching of fluorescence occurs as the distance between the label and
the protein increases as a function of time (Fig.
3). These results show that liposome fusion has taken place with the spheroplast membranes of H. salinarium. Fusion efficiency is estimated (33) and is found to be
in the range of 50-60%. In control experiments, neither spheroplasts nor liposomes alone showed any appreciable fluorescence change over a
1-h period. Spheroplasts alone do not show any detectable emission at
530 nm ( Lycopene Cycling and Subsequent Retinal Biosynthesis Is Induced by
the Presence of Membrane-bound bOp--
Pum Lycopene Cycling Is Inhibited by the Presence of bR--
When
spheroplasts of Pum Exogenously added Retinal Does Not Inhibit Lycopene
Cyclization--
It has been established that the conversion of
Purple membrane, a differentiated domain of the plasma membrane,
contains only one protein species, bacterioopsin, which is complexed
with retinal in a 1:1 stoichiometry. The biogenesis of purple membrane
is inducible by limiting the oxygen supply (34) which turns on the
synthesis of both bacterioopsin and retinal (35). In contrast, most of
the lipid molecules necessary for purple membrane formation are
synthesized long before the start of bacterioopsin and retinal
synthesis, i.e. lipids are taken from the pool of the cell
membrane (24, 35).
Most of the retinal present in halobacteria is associated with
bacterioopsin; hence, one observes a nearly stoichiometric relationship
between bacterioopsin and retinal content. This fact suggests the
existence of a highly efficient regulation mechanism coordinating the
bacterioopsin and retinal synthetic pathways. In a classic piece of
work by Sumper and Herrmann (24), it has been found that whereas bOp
may be the trigger for retinal biosynthesis from its precursors, it is
unclear which of the two (excess retinal or bacteriorhodopsin in the
membrane) generates the feedback signal to stop retinal biosynthesis.
From the existing data, the following questions emerge on events that
trigger retinal biosynthesis (Fig.
4):
(a) Which of the two steps (lycopene-to- (b) Which of the two events (bop transcription or
bop translation) acts as a trigger of retinal biosynthesis?
(c) If, instead of possibility b, protein product
bOp is the trigger, which form of the protein (unfolded nascent
polypeptide or folded polypeptide) acts as a trigger of retinal biosynthesis?
The results of the present study aimed at understanding the factors
triggering retinal biosynthesis show that both endogenously expressed
bOp and exogenously introduced bOp are converted into the retinal-bound
form, bacteriorhodopsin. A concomitant decrease in the lycopene content
and the formation of retinal suggests that the presence of the
apoprotein bOp has triggered the conversion of lycopene to The fact that bop mRNA as well as bOp triggers the
lycopene-to- Similarly, the following questions emerge regarding the trigger that
inhibits or stops retinal biosynthesis:
(a) Which of the two (excess retinal or bR) acts as a
trigger for inhibition?
(b) At what stage does the feedback signal operate,
e.g. at the lycopene-to- These questions are addressed by the in vivo introduction of
both bR and excess retinal. When bR is introduced into
Pum At present, neither the mechanism for how this triggering occurs nor
the mechanism for how retinal biosynthesis is initiated is clear. It is
not clear whether the trigger lies within trimeric unit formation. It
is also unclear what role, if any, halorhodopsin and/or sensory
rhodopsin play in retinal biosynthesis.
This is the first report on the in vivo liposome-mediated
introduction of macromolecules for the determination of factors regulating the biosynthesis of cofactors and their binding to proteins.
The approach is simple and novel and involves the in vivo
introduction of mRNA and membrane apoprotein into spheroplasts lacking the protein as well as the cofactor. Such a study could provide
information about the regulation of the pathway involved in the
synthesis of its cofactor.
We are grateful to Prof. A. K. Singh for
the gift of all-trans-retinal.
*
This study was supported by Grant SP/SO/D71/97 from the
Department of Science and Technology of the Government of India.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
To whom correspondence should be addressed. Tel./Fax:
011-91-22-576-7774; E-mail: sonar@btc.iitb.ernet.in.
The abbreviations used are:
bR, bacteriorhodopsin;
bOp, bacterioopsin protein;
CHAPS, 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid;
N-NBD-PE, N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-1,2-dihexadecanoyl-sn-glycero-3-phosphoethanolamine;
N-Rh-PE, rhodamine B
1,2-dihexadecanoyl-sn-glycero-3-phosphoethanolamine;
triethylammonium salt, Pum, purple membrane;
PAGE, polyacrylamide
gel electrophoresis;
FRET, fluorescence resonance energy
transfer.
Bacterioopsin-triggered Retinal Biosynthesis Is Inhibited by
Bacteriorhodopsin Formation in Halobacterium
salinarium*
and
ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-carotene in retinal biosynthesis. The
trigger for this event does not lie with either transcription or
translation of the bop gene. It is clearly associated with
the folded and the membrane-integrated state of bacterioopsin. On the
other hand, the trigger signaling inhibition of retinal biosynthesis
does not lie with the presence of excess retinal but with the correctly
folded, retinal-bound form, bacteriorhodopsin.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-carotene, followed by an
oxidation of -carotene to all-trans-retinal (7). Early
studies indicate that retinal biosynthesis in halobacteria may be
stringently regulated, and factors involved in such a control remain
poorly understood. There are four possible regulatory factors: (a) transcriptional events leading to bacterioopsin
mRNA, (b) the translation of bop mRNA to
bacterioopsin protein, (c) all-trans-retinal, and
(d) the folded chromoprotein bacteriorhodopsin.
) strains that initially contain neither
bacterioopsin nor retinal. Subsequent isoprenoid analysis shows that
bacterioopsin triggers the biosynthesis of retinal. Furthermore, to
determine the regulation leading to inhibition of retinal biosynthesis,
both excess retinal and chromoprotein bR were independently introduced
into Pum spheroplasts. These results show that although
bacterioopsin triggers retinal biosynthesis, it is the formation of
bacteriorhodopsin and not the excess of retinal that inhibits its biosynthesis.
EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
strains were obtained by screening several colonies
of H. salinarium S9 on agar plates as orange-colored
colonies. These colonies were further characterized using Southern
hybridization with a bop gene-specific probe, as described
previously (8). Two strains were found to be of the SD9 type and were
characterized as Pum, strains in which the bop
gene has been found to be inactivated by the insertion of the ISH1 type
of transposable element, as described previously (8, 9).
--
Two genes encoding bacterioopsin with
and without leader sequences were synthesized using synthetic
oligonucleotides and assembled as shown in Fig.
1. The 5'-region contains the
Shine-Dalgarno sequence for Escherichia coli expression (10)
and the bop leader sequence, as reported previously (11).
The remaining bop sequence was adapted as described by Dunn
et al. (12), with the minor modification of replacing the
3'-terminal EcoRI site with HindIII. Both genes
were cloned into pGEM3(z) vector (Promega, Madison, WI) at
EcoRI-HindIII sites.
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Fig. 1.
Construction of
pGEM-SBOP-L+/L for the
preparation of bop mRNA with and without leader
sequence. Genes were synthesized for bOp expression with and
without the leader sequences (see "Experimental Procedures").
Synthetic genes were cloned into pGEM3(z) in
EcoRI/HindIII sites.
were linearized
at HindIII sites, and the corresponding bop
mRNAs were obtained using in vitro T7-based
transcription (13).
-D-galactopyranoside-induced E. coli expression as described previously (13, 15).
E. coli-expressed bOp was refolded using halobacterial
lipids and all-trans-retinal (13) to obtain bR.
strains were grown in a medium (250 g of NaCl, 20 g of
MgSO4·7H2O, 3 g of trisodium
citrate·2H2O, 2 g of KCl, 3 g of Bacto yeast extract, and 5 g of Bacto tryptone per liter) at 37 °C
(doubling time, 14-18 h). For anaerobic growth, cells were grown
strictly in the presence of nitrogen and 0.5% arginine as described
previously (21). The cells were harvested in the mid-log phase
(turbidity, ~0.7-1.0 unit at 578 nm) by centrifugation (7,000 × g) at 30 °C and washed with the basal salt solution
that contained 250 g of NaCl, 20 g of
MgSO4·7H2O, and 2 g of KCl per liter.
Washed cells grown in a 250-ml culture were suspended in 10 ml of 4 M NaCl containing 25 mM KCl and 5 g/liter of
L-alanine (pH 7.5). A total of 2.5 ml of 0.5 M
EDTA (pH 7.5) were then added, and the suspension was incubated for 20 min at 37 °C. At this time, spheroplast conversion was complete.
and the FRET
Assay--
Proteoliposomes containing bOp or bR were fused with
spheroplasts by combining bOp/bR proteoliposome solution (2.5 ml of
proteoliposomes prepared as described above) and spheroplast suspension
(7.5 ml of suspension containing spheroplasts prepared from H. salinarium cells grown in 250-ml cultures). For the FRET fusion
assay, N-NBD-PE and N-Rh-PE (0.08 M
each) (when necessary) were incorporated into the bilayers of
proteoliposomes (22). Fluorescence measurements were carried out at
room temperature in a fusion buffer containing basal salt solution
adjusted to pH 7.4. Two min after adding 25 µl of the proteoliposome
solution, 75 µl of the spheroplast solution were added. The final
volume in the cuvette was 2 ml. Fluorescence measurements (excitation
at 465 nm; emission at 530 nm) were carried out as functions of time
over 1 h. To calibrate the fluorescence scale, the initial
fluorescence of the liposomes was taken as the zero level, and the
fluorescence at the maximum probe dilution (determined by the addition
of 0.5% Triton X-100) was taken as 100% (22). FRET fusion assays were
performed to determine the fusion efficiency of following
proteoliposome with Pum spheroplasts for three systems:
(a) N-NBD-PE + bR, (b)
N-NBD-PE + N-Rh-PE, and (c)
N-NBD-PE + bOp + N-Rh-PE.
-carotene
was carried out by adding 60 ml of 20% diethyl ether in
n-hexane, and the elution of retinal was carried out by a
further addition of 140 ml of the same solvent mixture. The elution of
lycopene was carried out with 40 ml of diethyl ether. The amount of
each compound obtained was calculated spectrophotometrically (25). The
values are expressed on a protein basis (26) as micrograms/gram of
cellular proteins.
RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
strain; (b) to see whether exogenously
added bOp triggers retinal biosynthesis, the apoprotein bOp was
introduced into spheroplasts via liposome fusion; and (c) to
distinguish between apoprotein- and chromoprotein (retinal-containing
protein)-mediated control, bR was introduced into spheroplasts via
proteoliposome fusion. Cells were lysed to assay the presence of bR and
to determine the change in isoprenoid composition (the amount of
lycopene, -carotene, and retinal). Lycopene is known to be a
precursor of retinal (27), and its presence has been used to track
retinal biosynthesis in halobacteria (7).
Strains Do Not Produce bR or
bOp--
Spheroplasts were prepared according to methods described
previously (20, 28). The viability of spheroplasts was determined by
titering them on spheroplast regeneration plates as described previously (29, 30), and it was found that spheroplasts were viable.
Fig. 2A shows SDS-PAGE
analysis of partially purified membranes from spheroplasts. The samples
subjected to SDS-PAGE were aliquoted before the sucrose density
gradient step (23). Fig. 2A (lane 2) shows the
clear absence of bOp in spheroplasts of Pum origin. The
absorption spectrum of a sample subjected to SDS-PAGE also shows a lack
of the characteristic absorption peak corresponding to bR at 560 nm
(Fig. 2A, inset), suggesting that spheroplasts of the
Pum strain do not produce bR or bOp.
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Fig. 2.
SDS-PAGE analysis of membrane fractions
isolated during bR purification. A, Coomassie
Blue-stained gel after 15% SDS-PAGE of various membrane fractions
aliquoted before the sucrose density gradient centrifugation step
during the isolation of bR from spheroplasts. Lane 1,
molecular weight markers; lane 2, membranes isolated from
the spheroplasts of Pum cells; lane 3,
membranes isolated from the spheroplasts of Pum cells
treated with Lipofectin lacking mRNA (see "Experimental
Procedures"); lane 4, membranes isolated from the
spheroplasts of Pum cells treated with
Lipofectin-associated bop mRNA; lane 5,
membranes isolated from the spheroplasts of Pum cells
fused with liposomes containing bacterioopsin; lane 6,
membranes isolated from the spheroplasts of Pum cells
fused with liposomes containing bR. Inset, the visible
absorption spectra of samples 3 and 4 before SDS denaturation. The
position of the arrow indicates bOp. B, Coomassie
Blue-stained gel after SDS-PAGE of membrane samples isolated after
sucrose density gradient purification and sucrose removal. Molecular
weight markers (lane 1); samples were collected at a density
corresponding to bR from Pum spheroplasts that were
lipofected with bop mRNA lacking leader sequence
(lane 2; growth time, 12 h) and bop mRNA
containing leader sequence (lanes 3 (growth time, 1 h)
and 4 (growth time, 3 h)). Arrows indicate
unprocessed (high molecular weight) and processed (low molecular
weight) bacterioopsin.
Strains Results in the Expression of bOp and the
Subsequent Formation of bR--
Fig. 2A shows that when
Lipofectin-mediated introduction of bop mRNA was carried
out in Pum spheroplasts, bacteriorhodopsin is produced in
the correctly folded form, as seen from SDS-PAGE (lane 4)
and the characteristic 560 nm absorption peak (13, 31) (Fig.
2A, inset). Sucrose density gradient
ultracentrifugation shows that bOp expression leads to its assembly as
a purple membrane lattice. This indicates that exogenously added
bop mRNA is translated efficiently in spheroplasts of
Pum cells. In a control experiment in which only
Lipofectin lacking mRNA was used, no bOp production was observed
(Fig. 2A, lane 3), thus indicating that the transfection
protocol did not induce a latent/preexisting bop gene.
Another control experiment in which bop mRNA was
lipofected into Pum cells and grown in the presence of
N2 gas (see below) showed that bR formation does not take
place. This is due to the inhibition of the oxidation of -carotene
to retinal. The newly isolated bR showed characteristic light-dark
adaptation and proton pumping activity (data not shown). These results
indicate that bOp translated from bop mRNA is integrated
into the membranes of halobacterial cells and binds to intrinsic
retinal to form a functional bacteriorhodopsin.
cells that were lipofected with bop
mRNA containing the leader sequence and where the spheroplasts had
yet to revert to normal cells (lane 3). Lane 4 shows the presence of both unprocessed bR and processed bR in
spheroplasts that were allowed to convert to normal cells. When
mRNA lacking the leader sequence was used in lipofection, no
detectable bOp expression was found (lane 2). This
observation is in agreement with previously reported works (11, 32) in
which it has been indicated that the leader sequence of bop
mRNA is essential for binding to the ribosomal binding site in
halobacteria. The hairpin structure formed by bop mRNA may also add to the intracellular stability of the exogenously introduced mRNA (11, 32).
strain of
H. salinarium. The isolation and purification of protein show that the exogenously introduced apoprotein bacterioopsin forms the
chromoprotein bacteriorhodopsin and is incorporated into the membranes
of H. salinarium (Fig. 2A, lane 5). After
reconstitution, the isolated chromoprotein exhibited normal proton
pumping activity, indicating that the protein is functional (data not shown).
ex, 465 nm).
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Fig. 3.
FRET analysis of fusion between spheroplasts
of Pum cells of H. salinarium and proteoliposomes. Fusion efficiency is
calculated from the observed increase in emission intensity of
N-NBD-PE as described previously (Ref. 33; see
"Experimental Procedures"). Pum spheroplasts were
fused with liposomes containing N-NBD-PE (as a donor) and
N-Rh-PE (as an acceptor) (
), proteoliposomes containing
N-NBD-PE (donor), N-Rh-PE (acceptor), and
bacterioopsin (
), and proteoliposomes containing N-NBD-PE
(donor) and bR (acceptor) (
).
spheroplasts
that were fused with bop mRNA, apoprotein bOp, or
chromoprotein bR were lysed to determine the key isoprenoid pigments
found in the retinal biosynthetic pathway (Table
I). The analysis of Pum+
cells shows a characteristic absence of lycopene, indicating its
efficient conversion to -carotene, which, in the presence of oxygen,
is spontaneously converted into all-trans-retinal (Table I,
column 1). In contrast, isoprenoid analysis of Pum cells
indicates the accumulation of lycopene and the absence of -carotene
and retinal (Table I, column 2). When Pum cells are
lipofected with bop mRNA, pigment analysis indicates that lycopene is consumed to form -carotene and
all-trans-retinal in agreement with bR formation (Table III,
column 3). The introduction of the bOp protein via proteoliposomes in
Pum cells also results in an increase in the
concentration of -carotene (Table I, column 4).
Analysis of terminal isoprenoids in the retinal biosynthetic pathway
Lycopene -carotene all-trans-retinal
cells were fused with liposomes
containing bR, the protein was found to be incorporated into the membranes of the regenerated cells. Pigment analysis of these cells
(Table I, column 5) showed lycopene accumulation and hence the
inhibition of the conversion of lycopene to -carotene by bR. The
exogenously introduced bR was isolated and found to be functionally
unaltered when checked for proton pumping (data not shown).
-carotene to retinal is a spontaneous and
oxygen-dependent process and is inhibited under anaerobic
conditions (7). Under anaerobic conditions, -carotene should
accumulate, and retinal should be absent. When spheroplasts of
Pum cells were lipofected with bop mRNA
and grown under anaerobic conditions, although bOp-induced
lycopene-to--carotene conversion is seen (Table I, column 6),
-carotene-to-retinal conversion remains inhibited. When excess
retinal is introduced in Pum cells lipofected with
bop mRNA under anaerobic conditions, excess retinal does
not seem to inhibit lycopene-to--carotene conversion (Table I,
column 7), as evidenced by the increased -carotene content in
contrast to the data shown in Table I, column 8. It should be noted
that if bR is introduced under similar anaerobic conditions in the
presence of excess retinal, no -carotene is formed (Table I, column
9), indicating that it is bR and not the excess retinal that is
inhibiting the lycopene-to--carotene conversion.
DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 4.
Schematic representation of retinal
biosynthesis and its regulation by bacterioopsin and
bacteriorhodopsin. Dotted lines indicate the effect
with which bR or bOp acts in an inhibitory ( 
ve) or
stimulatory (+ve) manner on the biosynthetic pathway.
-carotene
conversion or -carotene-to-retinal conversion) is triggered by bacterioopsin?
-carotene
and hence the formation of retinal. Furthermore, our results show that
this trigger operates at the lycopene-to--carotene conversion and
not at the -carotene-to-retinal conversion. It should be noted that
nicotine binding and oxygen dependence studies show that the
-carotene-to-retinal conversion is spontaneous (7, 35).
-carotene conversion indicates that the trigger does not
lie within the events associated with transcription or translation of
the bop gene. The next question is which form of bOp (the
totally unfolded form or the partially folded form) triggers retinal
biosynthesis. In the present study, bOp has been introduced as the
partially folded or membrane-integrated form. Due to the extreme
hydrophobicity of bOp (16) and the membrane-associated nature of
proteoliposomes, we rule out the possibility of direct introduction of
bOp in the cytoplasm of Pum spheroplasts. Furthermore,
the study of Driessen et al. (16) and our regeneration
experiments on proteoliposomes suggest that bOp was introduced only in
the correctly folded form. Thus, we conclude that bOp-mediated retinal
formation is not associated with the unfolded nascent polypeptide
present in the cytoplasm. Instead, the trigger is clearly associated
with the folded and the membrane-integrated form of bOp.
-carotene conversion or at the
-carotene-to-retinal conversion?
spheroplasts, lycopene accumulation occurs,
suggesting that the presence of bR triggers the inhibition of retinal
biosynthesis. In contrast, when excess retinal is introduced, no
lycopene accumulation/inhibition occurs, indicating that the trigger
signaling inhibition does not lie within the presence of excess
retinal. Also, when the Pum strain containing excess
retinal was allowed to grow anaerobically in the presence of bOp, it
did not inhibit bOp-induced lycopene-to--carotene conversion. Thus,
we conclude that it is the presence of bR that inhibits and then
regulates the lycopene-to--carotene conversion and imparts
stringency to retinal biosynthesis.
ACKNOWLEDGEMENT
FOOTNOTES
Supported by Council of Scientific and Industrial Research,
Government of India.
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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