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Plant Physiol. (1998) 118: 227-235
Differential Control of Xanthophylls and Light-Induced Stress
Proteins, as Opposed to Light-Harvesting Chlorophyll a/b
Proteins, during Photosynthetic Acclimation of Barley Leaves to Light
Irradiance
Marie-Hélène Montané,
Florence Tardy1,
Klaus Kloppstech, and
Michel Havaux*
Commissariat à l'Energie Atomique/Cadarache,
Département d'Ecophysiologie Végétale et de
Microbiologie, Laboratoire de Radiobiologie Végétale
(M.-H.M.), and Laboratoire d'Ecophysiologie de la
Photosynthèse (F.T., M.H.), F-13108 Saint-Paul-lez-Durance,
France; and F-13108 Saint-Paul-lez-Durance,
FranceInstitute of Botany, Hannover University,
Herrenhäuser Strasse 2, D-30419 Hannover, Germany (K.K.)
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ABSTRACT |
Barley (Hordeum
vulgare L.) plants were grown at different photon flux
densities ranging from 100 to 1800 µmol m 2
s1 in air and/or in atmospheres with reduced levels of
O2 and CO2. Low O2 and
CO2 partial pressures allowed plants to grow under high
photosystem II (PSII) excitation pressure, estimated in vivo by
chlorophyll fluorescence measurements, at moderate photon flux densities. The xanthophyll-cycle pigments, the early light-inducible proteins, and their mRNA accumulated with increasing PSII excitation pressure irrespective of the way high excitation pressure was obtained
(high-light irradiance or decreased CO2 and O2
availability). These findings indicate that the reduction state of
electron transport chain components could be involved in light sensing
for the regulation of nuclear-encoded chloroplast gene expression. In
contrast, no correlation was found between the reduction state of PSII
and various indicators of the PSII light-harvesting system, such as the
chlorophyll a-to-b ratio, the abundance of the
major pigment-protein complex of PSII (LHCII), the mRNA level of LHCII,
the light-saturation curve of O2 evolution, and the induced
chlorophyll-fluorescence rise. We conclude that the chlorophyll antenna
size of PSII is not governed by the redox state of PSII in higher
plants and, consequently, regulation of early light-inducible protein
synthesis is different from that of LHCII.
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INTRODUCTION |
Photosynthetic organisms adapt to changes in irradiance by
altering and optimizing the abundance of specific components in the
photosynthetic apparatus. For instance, acclimation to high irradiances
typically induces a decrease in the abundance of LHCII (Melis et al.,
1985 ; Anderson et al., 1995) and a concomitant accumulation of ELIPs
(Adamska et al., 1992; Pötter and Kloppstech, 1993). Reduction of
growth irradiance elicits the opposite responses. An increased amount
of LHCII is an adaptation to shade, since it enhances the efficiency of
light harvesting by the photosystems. ELIPs and their algal homolog,
the cbr protein, have strong homologies with LHCII (Grimm et
al., 1989). They are supposed to bind chlorophylls and carotenoids
(Levy et al., 1993; Green and Kühlbrandt, 1995) and to have a
photoprotective function as minor pigment antennae with a reduced
light-harvesting function and enhanced energy dissipation capacity
(Levy et al., 1993; Krol et al., 1995; Montané et al., 1997).
Alternatively, ELIPs may be involved in the repair of the PSII reaction
centers and/or the protein-pigment complexes in photoinhibitory light
(Adamska, 1997). Strong light stress is also known to stimulate
carotenoid synthesis (Jones and Porter, 1986). Particularly,
high-light-grown leaves are selectively enriched in carotenoids
involved in the xanthophyll cycle, namely violaxanthin, zeaxanthin, and
antheraxanthin (Demmig-Adams and Adams, 1992). The photoprotective
function of xanthophyll is well accepted, although the exact molecular
bases of this protection are still unclear (Demmig-Adams and Adams,
1992; Horton et al., 1996; Havaux, 1998).
Light-intensity-dependent changes in pigment-protein complexes are
primarily controlled at the level of the LHCII gene transcription (Silverthorne and Tobin, 1984; Escoubas et al., 1995). However, little is known about the system that senses differences in light intensity and converts that signal to changes in gene expression. It
seems unlikely that phytochrome and the blue-light receptor(s) are
directly involved in the light acclimation of photosynthesis (Anderson
et al., 1995; Walters and Horton, 1995; Durnford and Falkowski, 1997);
they are much more sensitive to spectral quality or
photoperiod than to PFD. Recent experimental data have been obtained in
algae that support the notion that LHCII (Lhcb1) gene transcription (compare with Paulsen [1995] for a comparison of different nomenclatures for Chl a/b complexes) is coupled to
irradiance through the redox status of some photosynthetic electron
carriers, possibly the PQ pool (Allen et al., 1995; Huner et al.,
1996).
Using electron transport inhibitors, Escoubas et al. (1995) observed
repression or induction of LHCII gene transcription by maintaining the
PQ pool reduced or oxidized, respectively. Similarly, growing algae at
low temperature simultaneously increases the excitation pressure on
PSII (i.e. the reduction level of its electron acceptors) and mimics
high-light acclimation (Maxwell et al., 1994, 1995). However, it is
unlikely that PSII alone is the primary redox sensor within
chloroplasts, because no strict quantitative relationship between PSII
excitation pressure and pigment content, Chl a/b, and LHCII
apoprotein abundance was found in algae grown at different temperatures
(Savitch et al., 1996). Possible alternative redox sensors include
thioredoxin (Danon and Mayfield, 1994), the Cyt
b6/f complex (Pearson et al., 1993),
or soluble photosynthetic metabolites such as ATP and NADPH (Melis et
al., 1985). Recently, it has been suggested that chlorophyll precursors
could also be plastidic factors involved in the light induction of
nuclear genes (Kropat et al., 1997).
In higher-plant chloroplasts the relation between PSII excitation
pressure and the level of carotenoid and light-harvesting pigment
complexes is elusive. Gray et al. (1996) reported that, in cereals,
increasing the PSII excitation pressure by decreasing the growth
temperature resulted in minimal adjustment to LHC polypeptides of PSII,
Chl a/b, or xanthophylls. Petracek et al. (1997) found that
accumulation of LHCII mRNA in tobacco seedlings was unaffected by DCMU
treatment. Montané et al. (1997) showed in barley that low light
at 5°C causes a strong decrease in LHCII mRNA but not in
polypeptides. They also observed an increase in ELIP mRNA and protein,
which took place during the first hours after the transfer to low light
in the cold, as it usually occurs in strong light at 25°C. Growth of
pea plants in the presence of sublethal concentrations of a PSII
inhibitor (SAN 9785), which blocks electron transport at a site close
or similar to that of DCMU, leads to a noticeable increase in the PSII
chlorophyll antenna size (Joshi et al., 1995), suggesting a role for
the reduction state of the PQ pool in the regulation of LHCII gene
expression. Bilger et al. (1995) found an apparent link between
xanthophyll-cycle pigment content and the photosynthetic capacity in
potato but not in tobacco.
The lack of conclusive evidence on the redox control of photosynthetic
acclimation of higher plants to the light environment has prompted us
to re-examine the pigment content and organization in leaves adapted to
various PSII excitation pressures in long-term experiments. In this
study PSII excitation pressure was modulated by manipulating the
CO2 and O2 concentrations
of the atmosphere in which plants were grown. By this means, different
PSII excitation pressures can be obtained under conditions of constant
PFD and temperature. The results presented here indicate that both the xanthophyll pigments and the ELIPs respond positively to the excitation pressure on PSII, whereas the LHCII abundance was correlated with the
light irradiance but not with the reduction of PSII.
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MATERIALS AND METHODS |
Plant Material and Growth Conditions
Barley (Hordeum vulgare L.) plants were grown for 2 weeks in a phytotron under controlled conditions of temperature
(23°C/20°C, day/night), light (100 or 350 µmol photons
m2 s1, 12 h
d1), and air humidity (70%). Plants were then
transferred to closed growth chambers (700 L in volume) in which the
gas composition of the atmosphere was strictly controlled (Fabreguettes
et al., 1994). Plants were adapted for 1, 3, 7, or 8 d in various
atmospheres at various PFDs. Air humidity, photoperiod, and temperature
remained unchanged.
Pigment Determination
Pigments were extracted from leaf discs in methanol. After
centrifugation and filtration, the samples were analyzed by
reversed-phase HPLC as described previously (Havaux and Tardy, 1996).
Chlorophyll Fluorescence
Chlorophyll fluorescence was measured with a PAM-2000 modulated
fluorometer (Walz, Effeltrich). The initial level of chlorophyll fluorescence, Fo, was measured with a dim-red
light modulated at 600 Hz after applying a 2-s pulse of far-red light.
The maximal level, Fm, of chlorophyll
fluorescence was determined with a 800-ms pulse of intense white
light (4000 µmol m2 s1). The maximal
quantum yield of PSII photochemistry was determined by
(Fm  Fo)/Fm. When leaves were
adapted to white light, the relative variable fluorescence, V, was
determined from Fm, Fo, and the steady-state level, F: (F Fo)/(Fm Fo) (Havaux et al., 1991). V is identical to
1 qp, where qp is the so-called
photochemical quenching coefficient.
Leaves were infiltrated with 50 µM DCMU for 30 min in
darkness. Chlorophyll fluorescence was induced by a red- light beam of
PFD 40 µmol m2 s1. The half-time of the
induced fluorescence rise was used as an indicator of the functional
chlorophyll antenna size of PSII (Malkin et al., 1981).
Photosynthetic O2 Evolution
Leaf discs 1 cm in diameter were placed in the hermetically closed
cell of a laboratory-constructed photoacoustic spectrometer previously
described (Havaux and Tardy, 1996). The samples were illuminated with
white light modulated at 19 Hz (50 µmol photons m2 s1). The
photochemistry was saturated with a strong background light of PFD = 4500 µmol photons m2
s1. Photosynthetic O2
evolution was measured and separated from the photothermal signal as
described by Poulet et al. (1983). The quantum yield of O2
evolution,  , in relative values was determined as the ratio between
the amplitude of the O2-evolution-related photoacoustic signal and the amplitude of the photothermal signal (Poulet et al., 1983). Photoacoustic measurements of were performed at a low CO2 concentration, presumably at the
CO2 compensation point. The light-saturation
curve of photosynthesis was determined by measuring the gradual
decrease in the quantum yield while progressively increasing the PFD of
a continuous white light. E of O2 evolution was
measured with a modulated blue-green light (25 µmol
m2 s1) obtained with a
combination of BG18 and BG38 filters (Schott, Mainz, Germany), and with
a far-red background light (730 nm, 18 W m2
approximately 110 µmol m2
s1). E was measured in state 1 after 15 min of
adaptation to the far-red light as the ratio of the
O2 evolution in the presence of far-red light to
the O2 signal in the absence of far-red light (Canaani and Malkin, 1984).
Isolation of mRNA and Northern Hybridization
Leaf samples were harvested every 3 h during the diurnal
phase at the indicated days after transfer of the plants into different atmospheres. Isolation and northern hybridization with LHCII and ELIP
cDNA probes were performed as described in detail elsewhere (Montané et al., 1997). Two exposure times with Bio Max films (Kodak) were systematically done to test for the linearity of the
signals. The blots were quantified with a scanner (Gel Doc 1000, Bio-Rad) and the corresponding software. DNA probes were cDNA inserts
of cloned barley genes. The small ELIP was HV90 (Grimm et al., 1989).
The LHC clone was a gift from Dr. K. Gausing (Aarhus University,
Aarhus, Denmark).
Analysis by SDS-PAGE and Immunoblotting
Leaf samples were harvested the same way as for mRNA analysis. The
procedures of protein extraction, electrophoresis, and immunoblotting
with rabbit anti-barley small ELIP or anti-barley LHCIIb
antibodies and quantification were as previously described by
Montané et al. (1997). Protein determination was according to the
method of Lowry et al. (1951). Ten micrograms was loaded per
slot for ELIP determination and a dilution of 1:300 was used for LHCII
determination. The separated proteins were blotted onto Westran
membranes (Schleicher & Schuell) blocked with 5% low-fat milk powder
(Ülzenia, Ülzen, Germany) in PBS 0.1%, Tween 20. The
antibody from rabbit was applied in fresh 5% milk in a 1:2,000 dilution overnight at 4°C, the next morning for 1 h at 20°C,
and then washed six times with PBS 0.1% and Tween 20. The goat
secondary antibody (anti-rabbit) conjugated with alkaline phosphatase
(A0418, Sigma) was applied at a 1:20,000 dilution for 2 h at
20°C. Determinations of phosphatase were as described previously
(Montané et al., 1997). Dilutions of 1:300 and 1:600 of the
protein extracts showed linearity of the signals. Quantification was
done the same way as for mRNA analysis.
| |
RESULTS |
V (1 qP) is nonlinearily related to the fraction of
closed PSII centers, i.e. the fraction of reaction centers with their primary quinone electron acceptor, QA, in the reduced state
([QA]/[QA]total)
(Havaux et al., 1991). Thus, V can be used as a semiquantitative indicator of relative changes in the reduction state of PSII reaction centers in plants exposed to changing environmental conditions. V was
measured in barley leaves adapted to different PFDs of white light.
Figure 1 shows that V increases with
increasing PFD, as expected. In air a V value of 0.5 was obtained at a
PFD of approximately 1500 µmol photons m2
s1. When the availability of the final electron
acceptors (O2 and CO2) was
reduced, PSII excitation pressure strongly increased. For instance, V
was 0.5 at 800 or 300 µmol photons m2
s1 in an atmosphere containing 70 µg
mL1 CO2 and
10% O2 or 20 µg
mL1 CO2 and 2%
O2, respectively. High PSII excitation pressures
could then be obtained at low or moderate PFDs by decreasing the
partial pressure of CO2 and
O2 in the gas environment.
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| Figure 1.
PSII excitation pressure, as measured by V, in
barley leaves exposed to different PFDs in different atmospheres ( ,
air;  , 70 µg mL CO2 and
10% O2;  , 20 µg mL
CO2 and 2% O2).
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Pigments
Based on the data shown in Figure 1, we grew barley plants under
different PSII excitation pressures created by manipulating the light
and gas environment. After 8 d of growth in the different environments listed in Table I, the
photosynthetic pigments were analyzed. When the PFD was increased in
air from 250 to 1800 µmol photons m2
s1, V increased from 0.08 to 0.6 and Chl
a/b of the plants that were exposed to this initial
excitation pressure increased from 2.50 to 2.73. This latter
modification suggests a reduction of the Chl-b-containing
light-harvesting antennae relative to the reaction centers of PSII.
Concomitantly, the pool size of the pigments of the xanthophyll cycle
increased from 15.1 ng mm2 to 35.3 ng
mm2.
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Table I.
Effects of various growth conditions leading to
different PSII excitation pressures (as measured by V) on the
chlorophyll (Chl) and carotenoid content, Chl a/b, and the
xanthophyll-cycle pigments pool (A+Z+V) in barley leaves
Plants were grown for 8 d under the different gas and light
conditions. Data are means ± SD of 3 to 10 separate
experiments.
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Growth at high PFD affected preferentially the xanthophyll-cycle
carotenoids, since the ratio between the sum of A+V+Z and the total
carotenoid content rose from 0.22 at 250 µmol photons m2 s1 to 0.32 at 1800 µmol photons
m2 s1. A high PSII excitation pressure
(V = 0.48) was also obtained in moderate light (750 µmol photons
m2 s1) when air was
replaced by a mixture of 70 µg mL1
CO2 and 10% O2 in nitrogen. Instead of
increasing, Chl a/b decreased to 2.34 (versus 2.62 in air at
the same PFD).
On a leaf-area basis, the xanthophyll-cycle carotenoids did not change
significantly. However, leaves grown in an atmosphere impoverished in
CO2 and O2 were much
thinner than leaves grown in air, so comparison of pigment contents on
a leaf-area basis is meaningless. The leaf-specific weight was 0.152 mg
mm2 in the former plants and 0.164 and 0.204 mg
mm2 in plants cultivated in air at 400 µmol
m2 s1 and 1500 µmol
m2 s1, respectively.
This problem was overcome by normalizing the A+Z+V content to the total
carotenoid content or to the total chlorophyll content.
The use of normalized values shows that leaves grown under a high PSII
excitation pressure in moderate light are enriched in xanthophyll-cycle
carotenoids: the ratio of A+Z+V to carotenoids was 0.27 and the ratio
of A+Z+V to chlorophylls was 0.070. These values are very close to the
values found in leaves grown at a similar excitation pressure at high
PFD (1500 µmol m2 s1)
in air (0.29 and 0.073, respectively), whereas the corresponding ratios
in leaves grown in air at low PFD were substantially lower (0.22 and
0.046). This is seen more clearly in Figure
2, which shows the A+Z+V content
normalized to the chlorophyll and carotenoid content as a function of V
in various PFDs and gas conditions. The xanthophyll-cycle pigment
content was correlated with the PSII excitation pressure. When the
CO2 and O2 partial
pressures were further reduced to very low levels (e.g. 20 µg
mL1 CO2 and 2%
O2), plant growth was dramatically inhibited and
very limited adjustment of the photosynthetic pigments took place (data not shown).
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| Figure 2.
Xanthophyll-cycle carotenoids pool (V+A+Z)
normalized to the total chlorophyll content or the total carotenoid
content ([V+A+Z]/chl, ; [V+A+Z]/car,  ) as a function of the
PSII excitation pressure (V) obtained by varying the PFD in air (closed
symbols) or by decreasing the CO2 and O2
content of the atmosphere (70 µg mL
CO2 and 10% O2, 750 µmol m2
s1, open symbols). The data were calculated from the data
of Table I.
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PSII Chlorophyll Antenna Size
Table II shows some chlorophyll
fluorescence characteristics of plants grown at low or high excitation
pressure in high- or low-intensity light. The maximal quantum yield of
PSII photochemistry was similar in plants grown in strong light in air
and in plants grown in moderate light under conditions of low
CO2 and O2 concentrations. In contrast, the induction of chlorophyll fluorescence in the presence
of DCMU was much faster in the latter plants (half-time of the
fluorescence rise approximately 11 ms) compared with the former ones
(21 ms) or to plants grown at low PSII excitation pressure (air and low
PFD, 16 ms). This indicates an increase in the functional PSII
chlorophyll antenna size in plants grown at reduced
CO2 and O2 concentrations,
thus confirming the Chl a/b data.
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Table II.
Effects of various growth conditions leading to
different PSII excitation pressures (as indicated by V) on the maximal
quantum yield of PSII photochemistry [(Fm Fo)/Fm], the half time (t1/2) of
the chlorophyll fluorescence rise in the presence of DCMU, and the E of
O2 evolution in barley leaves
Plants were grown for 8 d under the different gas and light
conditions. Data are means ± SD of three separate
experiments.
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A decreased Chl a/b can also result from a reduction of the
PSII-to-PSI ratio. This latter possibility can be excluded in our
experiments from the measurements of E shown in Table II. E is a
measure of the  / ratio, where and are the photochemical potential (quantum yield × light absorption) of PSII and PSI, respectively (Canaani and Malkin, 1984). Growth of plants under high
excitation pressure on PSII (in low light) did not decrease E. In
reality, E tended to increase, thus indicating a trend toward a
PSII/PSI activity imbalance in favor of PSII, as expected from the
larger PSII antennae.
Figure 3 shows the light saturation curve
of photosynthetic O2 evolution in the different
types of plants. O2 evolution was measured with
the photoacoustic technique at the CO2
compensation point. decreased much more rapidly with increasing PFD
in leaves grown in low CO2 and
O2. The PFD corresponding to a 50% decrease in
was 200 and 600 µmol m2
s1 for plants grown under high PSII excitation
pressure at moderate and high PFD, respectively. These results are
consistent with larger antennae of the photosystems in the former
plants. When O2 evolution was measured with a
Clark-type O2 electrode under CO2 saturation conditions, qualitatively similar
results were obtained (data not shown).
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| Figure 3.
Plots of the photoacoustically monitored in
barley leaves grown under different PSII excitation pressures induced
by different light and gas environments versus the PFD of the incident
light. , Air and 400 µmol photons m2
s1; , air and 1500 µmol photons m2
s1; , 70 µg mL
CO2 and 10% O2 at 750 µmol photons
m2 s1. Plants were grown for 8 d in
the different light and gas environments.
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LHCII was quantified by western-blot analysis. Figure
4 shows that the LHCII abundance
substantially decreased during growth in air at 1500 µmol
m2 s1, whereas the LHCII level
significantly increased when barley plants were transferred to low
CO2 and O2 in moderate
light (500 µmol m2
s1). Those changes were more marked after
3 d of exposure to the high PSII excitation pressure than after
7 d. One can suggest that, in the long term, other adaptive
changes in the photosynthetic system of leaves exposed to bright light
could result in a reduced need for small pigment antennae.
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| Figure 4.
Changes in LHCII abundance after transfer of
barley plants from air and low light (100 µmol m2
s1) to air plus strong light (1500 µmol
m2 s1) or to low CO2 and
O2 (50 µg mL CO2
and 3% O2) in moderate light (500 µmol m2
s1). The results are expressed relative to the LHCII
level before the transfer to the new growth regimes. Lanes on the gels
were loaded with equal protein content and were probed with
anti-LHCIIb antibodies. The LHCII abundance was measured
after 3 and 7 d of growth under the new conditions. Data are mean
values of three experiments with SD being lower than 15%
for all values.
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Table II and Figures 3 and 4 clearly show that the PSII chlorophyll
antenna size is not under the direct control of the PSII excitation
pressure in barley leaves.
Gene Expression
Because of the oscillation of the mRNA of ELIP and LHCII genes
(Kloppstech, 1985; Tavladorakis et al., 1989), samples were taken every
3 h during the photoperiod to get the peak value. Figure
5 A shows the level of LHCII mRNA in
2-week-old barley leaves grown for 1 or 3 d under low or high PSII
excitation pressure. Transfer of barley plants from low light (100 µmol photons m2 s1)
to strong light (1500 µmol m2
s1) in air dramatically reduced the mRNA level
to approximately 10% of the control level. This reduction is a
well-known response to strong light stress.
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| Figure 5.
Maximal level of LHCII mRNA and levels of ELIP
mRNA and protein in barley leaves grown for 1 (white bars) or 3 (black
bars) d under low or high PSII excitation pressure in air or in 50 µg
mL CO2 plus 3% O2.
Maximum quantum yield for PSII photochemistry
(Fm Fo)/Fm: 0.79 ± 0.01 after 3 d in air at 100 µmol photons m2
s1; 0.81 ± 0.01 after 3 d at 100 µmol
photons m2 s1 in low CO2 and
O2; 0.69 ± 0.02 after 3 d in air at 1500 µmol
photons m2 s1; and 0.74 ± 0.02 after
3 d at 500 µmol photons m2 s1 in low
CO2 and O2. Results are expressed relative to
the highest value. Data are mean values of three experiments, with
SD being always less than 15%.
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It is interesting that decreasing the CO2 and
O2 concentration to 50 µg
mL1 and 3%, respectively, did not induce
a reduction of the mRNA abundance, although the PSII excitation
pressure (V approximately 0.45) was similar to that obtained at high
light in air. Thus, the same excitation pressure on PSII resulted in
strikingly different effects on LHCII transcripts, depending on the way
high-excitation pressure was obtained. Figure 5B shows that, in
contrast to the LHCII mRNA, the level of ELIP mRNA, which until now was
known only as a response to cold and strong light stress, was closely correlated with the PSII excitation pressure but not with the PFD. A
similar observation was made when the abundance of ELIP was analyzed
(Fig. 5C). Virtually no ELIP was detected in barley leaves grown under
low PSII excitation pressure, whereas ELIPs accumulated in leaves
submitted to conditions of high excitation pressure on PSII. However,
at reduced CO2 and O2
partial pressures, ELIP mRNA accumulated at low and moderate PFDs (100 and 500 µmol m2 s1,
respectively), whereas the polypeptides accumulated only at moderate
PFD. These findings suggest that the redox-sensing mechanism acts at
the level of ELIP transcription and that another mechanism dependent on
the irradiance level is required for ELIP accumulation.
| |
DISCUSSION |
Our data support the hypothesis that the chloroplast redox poise
controls the transcription of nuclear-encoded genes in photosynthetic organisms (Allen, 1993; Allen et al., 1995; Huner et al., 1996). The
abundance of xanthophyll-cycle carotenoids and of ELIPs in barley
leaves was closely related to the reduction state of PSII, with high V
values being associated with the appearance of ELIPs and the
accumulation of xanthophylls (Figs. 2 and 5). These changes took place
independently of whether the PSII electron acceptor QA was reduced by increasing the light irradiance
or by decreasing the availability of the final electron acceptors in
moderate light. Disconnection between ELIP synthesis and light
irradiance was previously observed in leaves exposed to cold and light
stresses (Adamska and Kloppstech, 1994; Montané et al., 1997).
For instance, in barley leaves chilled at 5°C, high levels of ELIP
mRNA were detected at low light, which did not induce any ELIP
transcript at 25°C (Montané et al., 1997). Low temperature
noticeably increases excitation pressure on PSII (Havaux, 1987), so
this cold-induced accumulation of ELIPs can be interpreted, in the
light of our results, in terms of redox control of gene expression.
Induction of ELIPs was previously shown to be unrelated to the
formation of active O2 species (Adamska et al., 1993) or to photooxidative damage of the thylakoid membranes (Montané et al.,
1997). Moreover, in this study accumulation of ELIPs and xanthophyll
carotenoids occurred in the absence of appreciable photoinhibition of
PSII (Table II; legend of Fig. 5). Our results are also compatible with
the finding that ELIP transcription is specifically induced by PSII
light (blue-green light) but not by PSI light (red plus far-red light)
(Adamska et al., 1992). Exposure of leaves to strong PSII light is
expected to over-reduce the intersystem electron transport chain,
whereas PSI light oxidizes it. Our data also show that the excitation
pressure on PSII appears to be involved in regulation at the level of
gene transcription (Fig. 5). Effective accumulation of stress proteins
and "stress pigments" presumably requires another mechanism to
act translationally or posttranslationally and depends on PFD (Adamska
et al., 1992; Debel et al., 1994).
In algae cold treatment in low light was also reported to bring about
accumulation of xanthophyll-cycle pigments (Maxwell et al., 1995).
However, when cereals were transferred to low light at chilling
temperature, very little change in the xanthophyll content of the
leaves was found in response to steady-state reduction of
QA (Gray et al., 1996). Possibly, this
lack of photosynthetic adaptation in cold-treated higher plants could
result from the strongly reduced growth rate at low temperature, which
could perturb photosynthetic acclimation to high PSII excitation
pressure conditions. However, Adams et al. (1994) found seasonal
changes in the xanthophyll-cycle pool size in different plant species,
with a much larger pool present in the leaves examined during the
winter. The originality of our work is that different PSII excitation
pressures were achieved at constant and ambient temperature and in the
absence of any photosynthetic inhibitors, thus avoiding side effects of
chilling stress and unspecific effects of chemical treatments, allowing long-term experiments and significant growth of the plants. It was
previously reported that, after exposure for 7 d to different PFDs, the pool size of the xanthophyll-cycle pigments was
systematically higher in leaves of genetically manipulated potato
plants, which expressed an antisense mRNA coding for a key enzyme of
the Calvin cycle compared with wild-type leaves (Bilger et al., 1995).
As the drastic inhibition of the Calvin cycle activity in those
transformed plants is expected to cause a steady-state reduction of
photosynthetic electron carriers, this result can be seen as another
illustration of xanthophyll biosynthesis regulation dependent on the
reduction state of the electron transport chain. The apparent
coordination of the accumulations of ELIPs and xanthophyll-cycle
carotenoids found in the present study, with both phenomena responding
apparently to similar light switches, is consistent with the suggestion
that ELIP or its algal homolog and the xanthophyll cycle might be
interrelated in their biological function (Adamska et al., 1992, 1993;
Levy et al., 1993; Krol et al., 1995).
Although the amplitude of variable chlorophyll fluorescence is directly
related to the reduction state of QA (Havaux et
al., 1991), it is not possible to identify from our study the
photosynthetic electron carrier(s) involved in regulation of gene
expression. Since PQ reoxidation is the slowest step in the intersystem
electron transport chain (Haehnel, 1984), a high reduction level of
QA and a high V value are generally accompanied
by a reduction of the PQ pool and can also be associated with reduction
of components of the Cyt b6/f
complex. In this context, it is worth mentioning that strongly reduced
levels of Cyt b6/f complex in
transgenic tobacco markedly increase the excitation pressure on PSII
without significantly affecting the carotenoid content of the leaves
(Hurry et al., 1996). In fact, Cyt
b6/f is known to play a key role in the short-term response to light via the state-transition phenomenon (Wollman and Lemaire, 1988; Gal et al., 1987). The state
transitions are a mechanism by which chloroplasts adjust the
light distribution between PSII and PSI via reversible phosphorylation
of LHCII (Williams and Allen, 1987). It is believed that the
LHCII-kinase is directly associated with the Cyt
b6/f complex and that the activation
of the kinase system is mediated by the redox state of a component of
the Cyt b6/f complex (Gal et al.,
1990). As transcriptional regulation of nuclear-encoded genes by the
chloroplast redox status has been suggested to act through a signal
transduction pathway that is initiated by the action of a chloroplast
protein kinase (Allen, 1993; Escoubas et al., 1995), the Cyt
b6/f complex is a plausible candidate
as the primary redox sensor, as previously hypothesized by Pearson et
al. (1993). In the cyanobacterium Synechocystis, adjustment
of the stochiometry between PSI and PSII to light quality and
intensity was well correlated with the redox steady state of the Cyt
b6/f complex but not with the state
of the PQ pool (Murakami and Fujita, 1991).
ELIP and LHCII are usually known to respond to light stress in a
reciprocal manner (Pötter and Kloppstech, 1993). This behavior was confirmed in the present study when barley leaves were exposed to
strong light stress (Figs. 4 and 5). However, the main result of the
present work is that LHCII does not respond to the same light-sensing
mechanism as carotenoids and ELIPs. The PSII light-harvesting pigment
antenna size, probed by biochemical and functional measurements (Tables
I and II; Figs. 3-5), clearly decreased with increasing light
irradiance but not with increasing PSII excitation pressure. In fact,
high PSII excitation pressure in low light brought about an increase
rather than a decrease in the PSII antenna size, mimicking shade
adaptation. A similar, though less-pronounced, phenomenon was reported
in transgenic tobacco with reduced levels of Cyt b6/f complex (Price et al., 1995). In
the trangenic tobacco, high PSII excitation pressure in low light was
accompanied by a substantially reduced Chl a/b compared with
the wild type, suggesting reduced amounts of LHCII in the former
plants. The fact that ELIP was detected when antennae size increased,
remained constant, or decreased shows that ELIP accumulation and LHCII
disappearance are not strictly correlated. In this context, one should
remember that during greening, ELIP accumulation always precedes the
LHCII accumulation in chloroplast biogenesis when low amounts of
chlorophyll are present (Meyer and Kloppstech, 1984; Beator and
Kloppstech, 1994). Although this phenomenon could be related
to a different coupling to the circadian oscillator (Tavladorakis et
al., 1989), it is in favor of a distinct signal for LHCII and ELIP
regulation. We conclude from our data that the excitation pressure on
PSII and the redox state of the intersystem electron transport chain
are unlikely to be the primary redox sensors controlling LHCII gene
expression in barley leaves. Consequently, gene regulation during
photoacclimation of photosynthesis seems to differ in higher plants and
in green algae. The physiological and biochemical reasons for this
difference deserve to be studied in the future.
| |
FOOTNOTES |
1
Present address: Laboratoire de Chimie Physique
des Macromolécules aux Interfaces, Université Libre de
Bruxelles, B-1050 Bruxelles, Belgium.
*
Corresponding author; e-mail michel.havaux{at}cea.fr; fax
33-4-4225-6265.
Received March 23, 1998;
accepted May 29, 1998.
| |
ABBREVIATIONS |
Abbreviations:
A+Z+V, xanthophyll-cycle pigment complex,
composed of antheraxanthin, zeaxanthin, and violaxanthin .
Chl
a/b, chlorophyll a-to-b
ratio.
E, Emerson enhancement.
ELIP, early light-inducible protein.
LHCII, major light-harvesting Chl a/b-protein complex of
PSII.
PFD, photon flux density.
PQ, plastoquinone.
V, relative variable
chlorophyll fluorescence.
| |
ACKNOWLEDGMENTS |
We are grateful to Dr. M. Péan and the members of the
C23A unit (Département d'Ecophysiologie
Végétale et de Microbiologie, Commissariat à
l'Energie Atomique/Cadarache) for their help in growing plants in
controlled atmospheres.
| |
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Top
Abstract
Introduction