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Molecular and Cellular Biology, February 2000, p. 1116-1123, Vol. 20, No. 4
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Translation of Chloroplast psbA mRNA Is
Modulated in the Light by Counteracting Oxidizing and Reducing
Activities
Tova
Trebitsh,
Alex
Levitan,
Anat
Sofer, and
Avihai
Danon*
Department of Plant Sciences, Weizmann
Institute of Science, Rehovot 76100, Israel
Received 7 September 1999/Returned for modification 20 October
1999/Accepted 10 November 1999
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ABSTRACT |
Light has been proposed to stimulate the translation of
Chlamydomonas reinhardtii chloroplast psbA mRNA
by activating a protein complex associated with the 5' untranslated
region of this mRNA. The protein complex contains a redox-active
regulatory site responsive to thioredoxin. We identified RB60, a
protein disulfide isomerase-like member of the protein
complex, as carrying the redox-active regulatory site composed of
vicinal dithiol. We assayed in parallel the redox state of RB60 and
translation of psbA mRNA in intact chloroplasts. Light
activated the specific oxidation of RB60, on the one hand, and reduced
RB60, probably via the ferredoxin-thioredoxin system, on the other.
Higher light intensities increased the pool of reduced RB60 and the
rate of psbA mRNA translation, suggesting that a counterbalanced action of reducing and oxidizing activities modulates the translation of psbA mRNA in parallel with fluctuating
light intensities. In the dark, chemical reduction of the vicinal
dithiol site did not activate translation. These results suggest a
mechanism by which light primes redox-regulated translation by an
unknown mechanism and then the rate of translation is determined by the reduction-oxidation of a sensor protein located in a complex bound to
the 5' untranslated region of the chloroplast mRNA.
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INTRODUCTION |
During photosynthesis, the light
reactions produce deleterious by-products that lead to
photoinactivation of the photosystem II reaction center and concurrent
protein turnover (2, 37, 54). Thus, maintenance of
photosynthetic capacity requires de novo synthesis and replacement of
photodamaged proteins. The protein showing the highest rate of
synthesis at high light intensity in higher plants and algal cells is
D1 (a core protein of photosystem II encoded by psbA)
(18, 37, 54). However, photoregulated protein synthesis is
common to several additional photosynthetic proteins and is also
observed during chloroplast biogenesis (5, 15, 30, 31, 36).
Chloroplast gene expression is regulated by light during its
biogenesis at transcriptional and multiple posttranscriptional events
(reviewed in references 39, 40, 46, and
53). While in the mature chloroplast the demand for rapid response in gene expression, to accommodate an environment of
fluctuating light intensities, probably selected translation as a major
determinant of photoregulated gene expression (reviewed in references
11, 19, 39, and 53). Both
initiation and elongation steps of translation have been implicated as
light-regulated components of gene expression (5, 17, 27, 29,
56).
The 5' untranslated region (5'UTR) of several chloroplast mRNAs is
a major determinant of translation (9, 25, 38, 45, 48, 51, 52, 57,
58). In addition, genetic and biochemical evidence has suggested
that nucleus-encoded factors are essential to the translation of
chloroplast mRNAs in a gene specific manner (20, 26, 32,
51, 55, 57). The nucleus-encoded factors are thought to
enter the chloroplast and mediate translational regulation via the
5'UTR of chloroplast mRNAs (38, 48, 51, 57, 58).
A set of mRNA-binding proteins which bind to the psbA
5'UTR with high affinity and specificity have been identified and
purified from Chlamydomonas reinhardtii cells
(14). psbA 5'UTR-binding proteins are composed of
four proteins, RB38, RB47, RB55, and RB60. These form a complex
(psbA 5'PC) which binds the mRNA through the RB47
protein. The level of binding of psbA 5'PC to the mRNA parallels the level of psbA mRNA translation and
association with polyribosomes in light- and dark-grown wild-type
C. reinhardtii and in several mutants lacking translation of
psbA mRNA (14, 55, 56). This suggests that
light regulates polyribosome association and translation of
psbA mRNA by modulating the binding of psbA 5'PC to the 5'UTR.
Binding of psbA 5'PC to the mRNA is regulated by two
light-responsive molecular mechanisms. ADP-dependent
phosphorylation of RB60 inactivates psbA 5'PC at ADP levels
attained in chloroplasts only in the dark (12). Modulation
in vitro of psbA 5'PC-binding activity by a redox mechanism
suggested that the complex contains a redox-responsive regulatory site.
The reactivation of psbA 5'PC by dithiol reductants and not
by monothiol reductants predicted that the regulatory site is composed
of vicinal dithiols and is reduced in vivo by a thioredoxin-like
protein (13). A reductive signal transduced by the
ferredoxin-thioredoxin system of photosynthesis (6, 49) was
proposed to reduce the regulatory vicinal dithiol site (VDS) within the
psbA 5'PC, thereby activating translation of psbA
mRNA (13).
Lately, three components of psbA 5'PC, RB38, RB47, and RB60,
have been cloned. RB60 was shown to be a protein disulfide
isomerase-like protein (28), and RB47 has high homology to
poly(A)-binding proteins (55). RB38 shows no homology to
proteins with known function (55). Based on sequence
homology to thioredoxin-like proteins and redox regulation of
recombinant RB47 in vitro, RB60 was proposed to function equivalently
to chloroplast thioredoxins and transduce the redox signal directly
from thioredoxin reductase to RB47 (28).
A "light" signal transduced by a thioredoxin-like protein has been
proposed to activate psbA 5'PC by reduction of a regulatory VDS within the protein complex (13). This suggests that for perception of the reductive signal in vivo, the VDS has to be initially
oxidized. Hence, we needed to establish, in parallel, the redox state
in organello of the regulatory VDS and redox effects on D1 protein
synthesis in intact chloroplasts. Here we show that the regulatory VDS
is contained within RB60, the protein disulfide isomerase-like member
of psbA 5'PC, identifying RB60 as the redox sensor protein
of the 5'PC. We demonstrate that, similarly to activation of
psbA 5'PC (13), photoregulated translation of D1
is stimulated by a dithiol but not by a monothiol reductant, further
implicating VDS-containing proteins in redox-regulated translation of
psbA mRNA. We found that illumination of chloroplasts triggers specific oxidation of RB60, which is counteracted dynamically by a reductive activity. Under increased light levels, chloroplasts exhibit a higher rate of psbA mRNA translation and
contain a larger pool of reduced RB60, suggesting that a
counterbalanced action of reductive and oxidizing activities modulates
the translation of psbA mRNA in parallel with
fluctuating light intensities.
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MATERIALS AND METHODS |
Alga growth conditions and chloroplast isolation.
C.
reinhardtii cw15 cells were grown in TAP medium (23),
under a 12-h light/12-h dark regime at 25°C, to a density of
approximately 107 cells/ml. Intact chloroplasts were
collected from a 45%/70% interface of a discontinuous Percoll
gradient by a previously described method (4, 22). The
chlorophyll concentration was determined spectrophotometrically by
Arnon's method (1). Isolated chloroplasts were kept in the
dark for at least 30 min before being subjected to further treatments.
In organello translation and RNA isolation.
Protein
synthesis in intact chloroplasts (200 µg of chlorophyll/ml) was
performed as previously described (41) with slight modifications. All translation reaction mixtures included 10 mM MgATP.
Dark-adapted chloroplasts were preincubated for 10 min in the dark or
in the light in the presence or absence of 5 mM dithiothreitol (DTT),
10 mM 
-mercaptoethanol (-ME), or 10 mM diamide. Following
preincubation, the chloroplasts were pulse-labeled for 10 min with
[35S]methionine and then allowed to complete protein
synthesis in the presence of 5 mM unlabelled methionine. Proteins were
separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis
(SDS-PAGE) (34) and transferred onto nitrocellulose
membranes. Radiolabeled proteins were detected by autoradiography. The
location of proteins D1, D2, and the large subunit of ribulose
bisphosphate carboxylase/oxygenase was determined by immunoblot assays
using the corresponding antisera. Polysomal and total RNA was extracted
from light- and dark-incubated chloroplasts as previously described
(3). RNA extracted from equal amounts of chloroplasts (5 µg of chlorophyll) was fractionated, and RNA blots were hybridized
with the 32P-labeled psbA cDNA probe.
Identification of VDS-containing proteins.
psbA 5'PC
was isolated by RNA affinity purification as previously described
(12). psbA RNA affinity-purified proteins were labeled with
N-iodoacetyl-[125I]-3-iodotyrosine
([125I]IAIT) (21) in the presence of 0.5 mM
DTT or with [14C]phenylarsine oxide
([14C]PAO) (33) for 20 min at room
temperature. Labeled proteins were fractionated by SDS-PAGE
(34). [125I]IAIT-labeled proteins were
identified by autoradiography, and [14C]PAO-labeled
proteins were blotted onto nitrocellulose membranes and visualized with
a FujiX Bas 1000 PhosphorImager. Recombinant RB60 (rRB60; 140 ng),
expressed from RB60 cDNA (accession no. AF036939), was incubated for 5 min with 1 mM DTT, oxidized with 5 mM dithionitrobenzoate, or modified
with 5 mM n-ethylmaleimide for 5 min prior to labeling with
[125I]IAIT (21) for 5 min at room temperature.
Cloning of RB60 cDNA and purification of recombinant RB60.
A
lambda ZAPII cDNA expression library of C. reinhardtii was
screened using antibodies raised against RB60 (12). Four
clones were isolated from 105 plaques. In vivo excision of
pBluescript from the lambda vector was performed as specified by the
manufacturer (Stratagene, La Jolla, Calif.). Sequencing was performed
with universal and sequence-specific primers, using the
dideoxy-nucleotide terminator cycle sequencing method and an ABI model
373A sequencing system (Applied Biosystems, La Jolla, Calif.).
Nucleotide sequences were analyzed using the Sequence Analysis Software
Package (Genetics Computer Group, Madison, Wis.) (16). The
open reading frames of all four clones were identical and encode the
full-length sequence of RB60. A cDNA, containing the entire open
reading frame, was subcloned into the pQE expression vector in frame
with an amino-terminal His6 tag. Recombinant RB60
expression and purification was performed as specified by the
manufacturer (Qiagen, Chatsworth, Calif.).
In organello labeling with [125I]IAIT.
Chloroplasts for labeling were treated in parallel with chloroplasts
used for translation experiments. Following a 10-min incubation of
chloroplasts in the dark or in the light, chloroplast proteins were
labeled with [125I]IAIT (21) for 10 min at
room temperature. RB60 was immunoprecipitated with a rabbit anti-rRB60
serum and protein A/G PLUS-agarose (Santa Cruz Biotechnology, Inc.) as
recommended by the manufacturer. Total chloroplast proteins and
immunoprecipitated RB60 were separated by SDS-PAGE (34) and
blotted onto a nitrocellulose membrane. [125I]IAIT-labeled proteins were visualized by
autoradiography. The amount of precipitated RB60 in each treatment was
determined by an immunoblot assay using a mouse anti-RB60 serum. Total
chloroplast proteins labeled with [125I]IAIT were
precipitated with 10% trichloroacetic acid, and radioactivity was
measured using a TRIATHLER multilabel tester (HIDEX, Turku, Finland).
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RESULTS |
Light-regulated translation in isolated intact chloroplasts.
An isolated light-responsive intact-chloroplast translation system was
established for C. reinhardtii to study redox signaling of
photoregulated translation in chloroplasts. First, we tested whether
fully developed chloroplasts contain the regulatory components controlling light-regulated translation. MgATP (10 mM) was included in
all translation reaction mixtures to focus on photoregulatory events
that are independent of the energy status of the chloroplast. A small
set of proteins is clearly induced in chloroplasts incubated in the
light, in contrast to those incubated in the dark (Fig. 1B). The D1, D2, and large subunit of
ribulose bisphosphate carboxylase/oxygenase proteins, identified by the
immunoblot assay, show the highest level of light induction in isolated
intact C. reinhardtii chloroplasts. It is possible that the
synthesis of additional proteins, which require a longer time for light
induction or are unresolved in this electrophoresis system, is also
light stimulated. Light did not stimulate the synthesis of several
unknown proteins produced in the dark (Fig. 1B), indicating that light
does not act as a general stimulator of protein synthesis. The same
amounts of psbA mRNA (encoding the D1 protein) were
detected in dark- and light-incubated chloroplasts, confirming that the
amount of psbA mRNA present in the dark-incubated
chloroplasts was not limiting D1 synthesis (Fig.
2, lanes Total). These results are
similar to those found for whole cells (36) and indicate
that translation of psbA mRNA in intact chloroplasts is
regulated by light.
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FIG. 1.
Light-regulated translation in mature chloroplasts
isolated from C. reinhardtii cells. Intact C. reinhardtii cw15 chloroplasts were collected from a 45%/70%
interface of discontinuous Percoll gradient by published methods
(4, 22). Intact chloroplasts were incubated in the dark for
30 min, and an aliquot was transferred for 10 min into the light (150 µmol m 2 s1). The translational
activities of the dark-incubated (D) and light-incubated (L)
chloroplasts were then assayed by labeling newly synthesized proteins
for 10 min with [35S]methionine. The nascent
polypeptides were allowed to complete synthesis by incubation for an
additional 5 min in the presence of excess nonradioactive methionine.
Chloroplasts were lysed, and extracted proteins were
fractionated by SDS-PAGE and blotted onto nitrocellulose membranes. (A)
Amido Black staining of chloroplast proteins. (B) Autoradiograph of the
same blot as in panel A showing the 35S-labeled proteins.
LSU, large subunit of ribulose bisphosphate carboxylase/oxygenase.
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FIG. 2.
RNA blot showing light-regulated polysome association of
psbA mRNA in mature chloroplasts isolated from C. reinhardtii cells. RNA was isolated from chloroplasts treated as
for the experiment in Fig. 1. Equal amounts of total RNA and
polysome-associated RNA were loaded on the gel. A
32P-labeled psbA cDNA was used to probe the
blots.
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To determine whether light controls the initiation step or the
elongation step of translation, we assayed the association
of
psbA mRNA with ribosomes in dark- and light-incubated
chloroplasts.
The photoinduced recruitment of
psbA mRNA
to polysomes (Fig.
2,
lanes Polysomal) shows that in mature
chloroplasts, the initiation
step of translation is light controlled.
However, this does not
exclude additional light-regulated steps, such
as elongation.
Identical treatment of chloroplasts prior to light
incubation
ensured that the dramatic activation of translation was due
to
the light treatment only and occurred within the short time span
separating the two pools of light- and dark-treated chloroplasts.
Taken
together, these data suggest that a regulatory translational
factor(s)
controls the initiation of translation of
psbA mRNA
in
response to light. These results are consistent with the proposed
role
of
psbA 5'PC as a light-modulated
trans-acting
regulator
of initiation of
psbA mRNA translation
(
56).
Redox-regulated translation in isolated chloroplasts.
To test
whether translation of psbA mRNA in intact chloroplasts
is limited by an oxidized regulatory factor, we assayed whether translation of psbA mRNA could be enhanced by reducing
agents (Fig. 3). The hallmark of a
VDS is the insensitivity of its disulfide conformation to
reduction by monothiols and its sensitivity to dithiol reductants.
Thus, if translation of psbA mRNA is regulated by
a VDS-containing factor, such as psbA 5'PC, it should be
enhanced by DTT (a dithiol reagent) but not by -ME (a monothiol
reagent). Incubating illuminated chloroplasts with 5 mM DTT resulted in a clear increase in D1 synthesis (Fig. 3, lane 6) that was absent in
illuminated chloroplasts treated with an equimolar thiol concentration of -ME (lane 5). These data suggest that light-regulated translation of psbA mRNA in intact chloroplasts is controlled by a
redox-responsive factor containing a regulatory VDS, such as
psbA 5'PC, which upon reduction stimulates translation.
Incubating illuminated chloroplasts with the thiol oxidant diamide
diminished translation (lane 8). These properties are similar to those
predicted by the in vitro studies of redox-regulated binding of
psbA 5'PC (13), i.e., that thiol oxidation
inhibits and dithiol reduction stimulates translation.
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FIG. 3.
Light- and redox-regulated translation in mature
chloroplasts. Shown is an autoradiograph of an SDS-PAGE blot, showing
35S-labeled proteins from chloroplasts treated as for the
experiment in Fig. 1, except that a dithiol reductant (DTT), a
monothiol reductant (-ME), or a thiol oxidant (diamide) was added as
indicated in the figure.
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The stimulation of
psbA mRNA translation by DTT also
suggests that illuminating chloroplasts at 150 µmol m
2
s
1 was not sufficient to fully reduce the
intrachloroplast pool
of the redox-responsive factor(s) limiting
translation under the
experimental conditions used in this study. The
DTT treatment
enhanced the synthesis of other light-induced proteins
(Fig.
3,
compare lanes 6 and 4) but not of proteins synthesized in the
dark (compare lanes 6 and 1). This implies that regulation by
redox
mechanisms via VDS-containing proteins may be common to
light-activated
translation of other transcripts. Interestingly,
the responsiveness to
DTT was lacking in chloroplasts incubated
in the dark (lane 3). Also,
treating dark-incubated chloroplasts
with the thiol oxidant diamide did
not activate the translation
of
psbA mRNA (data not
shown). This indicates that, in contrast
to illuminated chloroplasts
(lane 6), translation is not limited
by oxidation or reduction in the
dark. These results also indicate
that inhibition of translation in the
dark is mediated by a nonredox
component that is a prerequisite (a
priming component) for redox
regulation. Taken together, these results
suggest that redox regulation
is active only in illuminated
chloroplasts in which oxidizing
and reductive signals modulate the
translation of light-induced
proteins.
Biochemical identification of the regulatory VDS-containing protein
of psbA 5'PC.
To characterize the redox state of the
regulatory VDS of psbA 5'PC in photoregulated translation in
chloroplasts, we first identified the protein containing it. A highly
purified preparation of psbA 5'PC contains four major
proteins, RB38, RB47, RB55, and RB60 (Fig.
4A, lane 1), each of which could
potentially contain the regulatory VDS. To ensure the correct
identification of the authentic VDS-containing protein(s), we used
highly purified preparations of psbA RNA affinity-purified
proteins (lane 1) in two independent experiments. (i) We first assayed
for covalent labeling of highly reactive thiols of
psbA 5'PC with [125I]IAIT under conditions
that preferentially label VDS (21). Only one protein,
RB60, was labeled by [125I]IAIT (Fig. 4A, lane 2).
(ii) We used [14C]PAO, which specifically binds to
VDS (33). [14C]PAO also bound only to the RB60
polypeptide (lane 3). These results indicate that RB60 is the only
VDS-containing protein in psbA 5'PC and that it is the
regulatory VDS-containing protein (13).
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FIG. 4.
Identification of the regulatory VDS-containing protein.
(A) Lanes: 1, Coomassie blue-stained SDS-PAGE of a highly purified
preparation of psbA 5'PC (Stained PC) isolated from C. reinhardtii cells using psbA RNA-affinity
chromatography; 2, PhosphorImage of SDS-PAGE of psbA 5'PC
labeled with [125I]IAIT (IAIT-labeled); 3, autoradiograph
of SDS-PAGE of psbA 5'PC labeled with [14C]PAO
(PAO-labeled). (B) Autoradiograph of SDS-PAGE of recombinant RB60
labeled with [125I]IAIT. Lanes: 1, protein reduced with
DTT; 2, protein oxidized with dithionitrobenzoate (DTNB); 3, protein
modified with n-ethylmaleimide (NEM).
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To use IAIT as a probe to characterize the redox state of RB60, we
first verified that binding of [
125I]IAIT to purified
RB60 is dependent on the redox form of the
protein. Equal amounts of
purified recombinant RB60, expressed
from RB60 cDNA, were incubated
under different redox conditions
with [
125I]IAIT. As seen
in Fig.
4B, [
125I]IAIT bound only the reduced form
of RB60 (Fig.
4B, lane 1).
No binding was detected when
[
125I]IAIT was incubated with either oxidized RB60 with
dithionitrobenzoate
(lane 2) or RB60 modified with
N-ethylmaleimide (lane 3). We concluded
that
[
125I]IAIT can be used to probe the redox state of
RB60.
Light modulates the redox state of RB60 and psbA
mRNA translation in chloroplasts.
Previous results suggested
that light regulates psbA mRNA translation by modulating
the redox state of a VDS intrinsic to psbA 5'PC. Reduction
of the VDS activates psbA 5'PC, and oxidation diminishes its
activity (13). The enhancement of psbA mRNA
translation by DTT in chloroplasts illuminated at 150 µmol
m2 s1 (Fig. 3, lane 6) predicts that the
pool of the VDS-containing factor controlling translation of
psbA mRNA was partially oxidized. The insensitivity to
DTT in dark incubated chloroplasts (lane 3) and the lack of response to
oxidation by diamide imply that in contrast to illuminated
chloroplasts, translation of psbA mRNA is not regulated
by redox mechanisms in the dark. To determine the redox state of the
pool of RB60 in the chloroplast under these two conditions, we isolated
RB60 by immunoprecipitation from light- and dark-incubated chloroplasts
that were labeled with [125I]IAIT (Fig.
5A, lanes IP). Labeling of RB60 was
significantly lower in response to light, showing that the pool of RB60
is more oxidized in the light than in the dark (Fig. 5A, lanes IP, and Fig. 5C). These results are consistent with the stimulatory effect of
DTT on psbA mRNA translation in the light and not in the
dark and suggest that oxidation of RB60 is activated in the light.
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FIG. 5.
In vivo characterization of the redox state of RB60 and
total proteins in dark- and light-incubated chloroplasts. (A)
Autoradiograph of immunoprecipitation assays of RB60 (IP) conducted
with extracts from isolated chloroplasts treated for 10 min in the dark
(D) or light (L), followed by [125I]IAIT labeling. Total
[125I]IAIT-labeled proteins (without immunoprecipitation)
(Total) represent 5% of the amount used for immunoprecipitation
assays. (B) The same blot as in panel A, probed with anti-RB60 sera
showing equal loading of RB60 protein. (C) Quantification of
[125I]IAIT-labeled RB60 (as determined by PhosphorImager
analysis and normalized for equal amounts of precipitated RB60 protein)
in 10-min light- and dark-treated chloroplasts. Values are means of six
independent experiments, and the light value is expressed as percentage
of the corresponding dark value (in each experiment designated as 100%
of [125I]IAIT-labeled RB60). (D) Quantification of total
chloroplast proteins labeled with [125I]IAIT, showing
that light does not affect the global protein thiol state in the
chloroplast. Each value is an average of three replications.
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The addition of DTT to illuminated chloroplasts resulted in higher
[
125I]IAIT labeling of RB60 (data not shown),
demonstrating that labeling
of RB60 was limited by oxidation and not by
some other unknown
modification(s) of RB60. To determine whether light
affects the
redox state of the majority of chloroplast proteins in the
same
manner as it affects RB60, the amount of
[
125I]IAIT-labeling of total proteins in illuminated or
dark-incubated
chloroplasts was assayed. In contrast to RB60, the redox
state
of the majority of chloroplast proteins was not affected by
illumination
(Fig.
5A, lanes Total, and Fig.
5D). This is in accordance
with
previous results showing that the reduced/oxidized ratio of
glutathione
or ascorbate does not change in chloroplasts between light
and
dark conditions (
24,
35). Thus, protein oxidation in the
light
is not a general chloroplast phenomenon but is specific to RB60
and, possibly, to other regulatory
proteins.
Perception of reductive signals in the intrachloroplast reducing
environment requires a counteracting oxidizing activity.
The partial
oxidation of the pool of RB60 in the light compared
to the dark (Fig.
5A, lanes IP, and Fig.
5C) suggests that RB60
oxidation is light
activated and then is rendered receptive to
the reductive
photosynthesis-derived signal. This hypothesis predicts
that the
steady-state amount of reduced RB60 molecules and hence
the rate of
psbA mRNA translation in the light are consequences
of
antagonistic reducing and oxidizing activities. Thus, the pool
of
reduced RB60 should increase in response to increased light
intensity.
To test this, we characterized, in parallel, the redox
state of RB60
(Fig.
6) and
psbA mRNA
translation (Fig.
7) under
increased
light regimes. We conducted two types of experiments:
in the first,
chloroplasts were exposed to increased light intensities
(Fig.
6A and
7, lanes L125 and L250), while in the second, serial
dilution of
chloroplasts incubated at constant light intensity
was used to obtain
increased average chloroplast light exposure
at lower chloroplast
concentrations (Fig.
6B, and
7, lanes L1
to L3). The results of both
experiments show that the pool of
RB60 is reduced in response to
increased light intensity (Fig.
6A) or higher average chloroplast light
exposure (Fig.
6B) while
the rate of
psbA mRNA
translation parallels the reduced state
of RB60 (Fig.
7). These data
are consistent with previous results
obtained from in vitro biochemical
analyses (
13) and highlight
an important component of redox
regulation, i.e., the specific
oxidation of RB60 in illuminated
chloroplasts.
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FIG. 6.
The redox state of the pool of RB60 in chloroplasts
incubated in different light regimes. (A) The redox state of the pool
of RB60 was determined as for the experiment in Fig. 5A, except that
immunoprecipitation assays were performed using proteins of
chloroplasts incubated in the dark (D) and under 125 (L125) or 250 (L250) µmol of light m2 s1.
Quantification was performed as for the experiment in Fig. 5C, except
that each value is an average of three replications (one replication of
the dark treatment was designated as 100% of
[125I]IAIT-labeled RB60). (B) The redox state of the pool
of RB60 was determined as for the experiment in Fig. 5A, except that
immunoprecipitation assays were performed with proteins of chloroplasts
incubated in the dark or in the light (150 µmol
m2 s1) at decreasing chloroplast
concentrations, resulting in an increasing average light exposure of
the chloroplasts. L1, 10 µg; L2, 5 µg; L3, 2.5 µg.
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FIG. 7.
Effect of different light regimes on protein synthesis
in mature isolated chloroplasts. Shown is an autoradiograph of protein
labeling performed as for the experiment in Fig. 1, under the
same light conditions as for the experiment in Fig. 6. LSU, large
subunit of ribulose bisphosphate carboxylase/oxygenase.
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DISCUSSION |
The most compelling information on the way the redox signal is
transduced by thioredoxins and regulates the activity of
redox-responsive proteins comes from studies of chloroplasts. Reducing
equivalents, generated from light by the concerted activities of
photosystem II and photosystem I, are probably used via ferredoxin,
ferredoxin-thioredoxin reductase, and thioredoxin to reduce regulatory
redox-active sites of key proteins involved in CO2
assimilation, ATP synthesis, and translation of psbA
mRNA (6, 13, 47, 49). An important characteristic shared
by the regulated redox-responsive proteins is their preferential
reduction by thioredoxins (mimicked by the dithiol reductant DTT and
not by monothiol reductants, such as -ME) (6). Here we
identified RB60 as the subunit of psbA 5'PC containing a
regulatory VDS (Fig. 4), previously implicated as prescribing
preferential responsiveness of psbA 5'PC to thioredoxin and
DTT (13). We show that photoregulated translation of D1 in
intact chloroplasts is regulated at the level of initiation and is
preferentially responsive to DTT (Fig. 2 and 3). These characteristics
are consistent with the proposed role of psbA 5'PC as a
light-modulated trans-acting regulator of initiation of
psbA mRNA translation (56). Preferential
responsiveness to DTT of photoregulated synthesis of the D2 protein and
large subunit of ribulose bisphosphate carboxylase/oxygenase proteins
was observed as well (Fig. 3), suggesting that the VDS-containing
protein(s) may also regulate the translation of these photosynthetic proteins.
Similarly to the cytosol, the chloroplast contains an antioxidative
system which under normal conditions maintains a reducing intrachloroplast environment (43). Regulation by redox
mechanisms requires both reductive and oxidizing activities. Therefore,
studies of redox signal transduction in intact chloroplasts, containing an active antioxidative system, are important to the elucidation of the
molecular role of redox-active factors. Thioredoxin-regulated enzymes
in chloroplasts incubated in the dark are activated by DTT, suggesting
that they oxidize in the absence of the photosynthetic reducing
potential in the dark (6). It was estimated that the fructose bisphosphatase/thioredoxin f system has a tendency for oxidation equivalent to disulfide bond formation in extracellular proteins (10). Here we show that treatment with the dithiol reductant DTT or the thiol oxidant diamide failed to stimulate the
translation of psbA mRNA in dark-incubated chloroplasts
(Fig. 3, lane 3). This suggests that translation of psbA
mRNA is not limited by reduction or oxidation in the dark and that
the inhibition of translation in the dark is mediated by a nonredox
component. The inactivation of psbA 5'PC by ADP-dependent
phosphorylation of RB60 at ADP levels attained in chloroplasts only in
the dark (12) could potentially perform this function. The
stimulation by DTT of psbA mRNA translation in
illuminated chloroplasts (Fig. 3, lane 6) and the inactivation by
diamide (lane 8) suggest that redox regulation is active in the light
and that the pool of redox-regulatory protein controlling translation
is partially oxidized in the light. Here we showed that the regulatory
VDS, contained in RB60 (Fig. 4), is oxidized in illuminated
chloroplasts in a specific manner (Fig. 5). The oxidation of RB60 in
the presence of the antioxidative system in intact chloroplasts (Fig.
5) suggests that the redox state of RB60 is not functionally affected
by of the global redox state of the chloroplast and is responsive only
to reduction by thioredoxin-like proteins.
According to this hypothesis, the redox state of the pool of RB60 and,
consequently, translation of psbA mRNA in the light is
determined by a counterbalanced action of reductive and oxidizing activities (Fig. 8). The reductive
activity is mediated by a thioredoxin-like protein, transducing
photosynthetic reducing equivalents, and is proportional to the
light intensity absorbed by photosynthesis. The nature of the oxidizing
activity of RB60 is unknown and is being investigated by us.
Light-triggered oxidation of RB60 could be mediated analogously to
thioredoxin-regulated enzymes by autooxidation of RB60 induced by the
priming pathway or alternatively by a specific light-activated
oxidizing factor. Our hypothesis predicts that both translation of
psbA mRNA and the pool of reduced of RB60 should
increase in higher light intensity. To test this, we characterized in
parallel the redox state of RB60 and psbA mRNA
translation under increasing light intensity (Fig. 6 and 7). The
results showed that the pool of RB60 becomes reduced in response to the
increase in average chloroplast light exposure (Fig. 6) and that the
rate of psbA mRNA translation parallels the reduced
state of RB60 (Fig. 7). These results suggest a mechanism by which
light primes redox-regulated translation by an unknown mechanism (Fig.
8). The inactivation of psbA 5'PC by ADP-dependent
phosphorylation of RB60 (12) implicates protein
phosphorylation and dephosphorylation as part of the priming event. Then, the rate of translation is determined, in parallel with
changes in light intensity, by the reduction-oxidation of a
sensor protein, RB60, located in a complex bound to the 5'UTR of
psbA mRNA. A direct benefit of such a regulatory scheme
is a dynamic capacity to stimulate translation under higher light intensities and to decrease translation as the light intensity diminishes. Such a dynamic regulation is required to maintain efficient
energy conversion in an environment of fluctuating light levels.
View larger version (46K):
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|
FIG. 8.
A working model for redox signaling in light-regulated
translation. The redox state of the regulatory VDS of RB60 controls the
RNA-binding capacity of psbA 5'PC, which binds the RNA
through the RB47 protein. Oxidation of the regulatory VDS inactivates
and reduction activates binding of the PC to the 5'UTR of
psbA mRNA and consequently psbA mRNA
translation. Light regulates translation via a prerequisite (priming)
redox-independent pathway and a redox-dependent pathway. The priming
pathway probably involves dephosphorylation and specific oxidation of
the pool of RB60 (either by autooxidation or by an RB60-specific
oxidizing factor), rendering RB60 receptive to the reductive signal
transduced by the redox-dependent pathway. In the redox-dependent
pathway, light energy is captured by the thylakoid-associated
photosynthetic complexes to produce reducing potential. Photosynthetic
reducing equivalents are transduced by ferredoxin (Fd),
ferredoxin-thioredoxin reductase (FTR), and thioredoxin (Trx) to reduce
the regulatory VDS of RB60. Hence, in the light, a counterbalanced
action of reducing and oxidizing activities modulates the redox state
of the pool of RB60 and consequently the translation of psbA
mRNA, in parallel with fluctuating light intensities. Transfer to
the dark activates phosphorylation and inactivates the oxidation of
RB60, resulting in an inactive form of psbA 5'PC that is not
redox responsive. The encircled P denotes an inorganic phosphate.
|
|
What is the receptor(s) perceiving the light signal(s) activating
translation of chloroplast mRNAs? Light regulates the expression of
both nuclear and chloroplast genes. In the chloroplast, the light
reactions of photosynthesis produce regulatory signals. Recent
experiments have implicated the redox state of plastoquinone as a
regulator of transcription of specific chloroplast genes and thylakoid
protein phosphorylation (7, 44). A second reductive signal
is probably transduced from photosystem I by the ferredoxin-thioredoxin system and regulates the activity of Calvin cycle enzymes,
thylakoid-coupling factor I, translation of chloroplast mRNAs, and
thylakoid protein phosphorylation (6, 7, 13, 50).
Cytoplasmic and nuclear photoreceptors have been identified as
regulators of plant development and adaptive responses to environmental
changes (reviewed in references 8 and
42). At least two photoreceptors, PhyA and PhyB,
affect chloroplast biogenesis (42).
It is possible that photoreceptors residing outside the chloroplast
perceive the light signal regulating translation of chloroplast mRNA. Here we demonstrated that fully developed chloroplasts
contain the components required for light signal perception and
transduction and for regulation of psbA mRNA translation
(Fig. 1 and 2). This suggests that the capacity to perceive and
transduce the light signal activating translation is not dependent on
light signals outside the chloroplast. Furthermore, we showed that the
light signal has two components, a nonredox component and a redox
component, and that the nonredox component is a prerequisite for the
redox component (Fig. 3). The redox component is composed of a
reductive signal, suggested to emanate from photosystem I
(13), and a counteracting oxidizing component (Fig. 3, 5,
and 6). Our data suggest that the light signals controlling both the
oxidizing component and the priming nonredox component originate from
within the chloroplast. The separation of chloroplast from cytoplasmic signaling pathways, resulting from studies of translation in isolated chloroplasts, may help elucidate the source of these light signals.
| |
ACKNOWLEDGMENTS |
We thank Z. Adam and E. Harel for help with chloroplast isolation
procedure, and we thank G. Galili, M. Edelman, G. Schuster, and R. Fluhr for their critical reading of the manuscript.
[14C]phenylarsine oxide was courtesy of T. Schäefer, and [125I]IAIT was a generous gift of C. Gitler.
A.D. holds The Judith and Martin Freedman Career Developmental Chair.
This work was supported by a grant from Dorot Science Fellowships
Foundation and a grant from the Minerva Foundation. T.T. is a recipient
of a Feinberg Post-Doctoral Fellowship. A.L. is a recipient of a
Feinberg Graduate School Fellowship.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department
of Plant Sciences, Weizmann Institute of Science, Rehovot 76100, Israel. Phone: 972-8-934-2382. Fax: 972-8-934-4181. E-mail:
Avihai.Danon{at}weizmann.ac.il.
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Abstract
Introduction
