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Plant Physiol, May 2001, Vol. 126, pp. 388-396
A New Approach to Measure Gross CO2 Fluxes in Leaves.
Gross CO2 Assimilation, Photorespiration, and Mitochondrial
Respiration in the Light in Tomato under Drought Stress
Silke
Haupt-Herting,
Klaus
Klug, and
Heinrich P.
Fock*
Fachbereich Biologie der Universität, Postfach 3049, D-67653
Kaiserslautern, Germany
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ABSTRACT |
We developed a new method using 13CO2 and
mass spectrometry to elucidate the role of photorespiration as an
alternative electron dissipating pathway under drought stress. This was
achieved by experimentally distinguishing between the CO2
fluxes into and out of the leaf. The method allows us to determine the
rates of gross CO2 assimilation and gross CO2
evolution in addition to net CO2 uptake by attached leaves
during steady-state photosynthesis. Furthermore, a comparison between
measurements under photorespiratory and non-photorespiratory conditions
may give information about the contribution of photorespiration and
mitochondrial respiration to the rate of gross CO2
evolution at photosynthetic steady state. In tomato
(Lycopersicon esculentum Mill. cv Moneymaker) leaves, drought stress decreases the rates of net and gross CO2
uptake as well as CO2 release from photorespiration and
mitochondrial respiration in the light. However, the ratio of
photorespiratory CO2 evolution to gross CO2
assimilation rises with water deficit. Also the contribution of
re-assimilation of (photo) respiratory CO2 to gross
CO2 assimilation increases under drought.
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INTRODUCTION |
Water deficit limits plant growth
and productivity because it decreases net CO2
assimilation due to reduced stomatal conductance for
CO2 and/or because of non-stomatal effects like
inhibition of enzymatic processes by changes in ionic or osmotic
conditions (Lawlor, 1995 ). At high light intensities the lowered
consumption of redox equivalents in the Calvin cycle makes it necessary
to degrade photosynthetic electrons in processes other than
CO2 fixation to avoid photo-inhibition. Sharkey
et al. (1988) showed that the activity of photosystem II can be
regulated in a way that the rate of electron transport matches the
capacity of the electron consuming reactions and that linear electron
transport depends not only on light intensity and
CO2 concentration but also on the
O2 concentration. Oxygen can function as
alternative electron acceptor directly in the Mehler reaction or
indirectly in photorespiration (Badger, 1985).
By combined measurements of O2 and
CO2 gas exchange it should be possible to
investigate the distribution of photosynthetic electrons between the
electron consuming reactions CO2 assimilation, photorespiration, and Mehler reaction (Haupt-Herting, 2000). The influence of drought stress on photosystem II activity, gross O2 evolution, and gross O2
uptake in tomato (Lycopersicon esculentum Mill. cv
Moneymaker) plants has been published elsewhere (Haupt-Herting and
Fock, 2000). This paper deals with the corresponding carbon fluxes
determined by a new CO2 gas exchange method.
The magnitude of photorespiration and the role of mitochondrial
respiration in the light under drought stress are still unclear. There
are studies where photorespiration decreases under drought stress
(Thomas and André, 1982; Biehler and Fock, 1995; Tourneux and
Peltier, 1995) as well as studies where it increases (Renou et al.,
1990; Biehler and Fock, 1996) or is not influenced at all (Stuhlfauth
et al., 1990). According to Bradford and Hsiao (1982) respiration in
the light declines with water deficit as dark respiration does. On the
other hand, Lawlor (1995) assumes that dissimilation is stimulated
under drought stress. However, the contribution of mitochondrial
respiration to CO2 release or O2 uptake at photosynthetic steady state has not
been resolved yet.
Photorespiratory CO2 evolution is accompanied by
CO2 uptake in the Calvin cycle and
CO2 release from mitochondrial respiration in the
light, whereas photorespiratory O2 uptake is
masked by O2 evolution at photosystem II and
O2 consumption by Mehler reaction and
mitochondrial respiration. Therefore, the determination of the rates of
photorespiratory CO2 evolution and
O2 uptake is difficult.
Rough calculations of photorespiration have been tried by different
methods in the past (Jackson and Volk, 1970; Catzky et al., 1971).
Progress in photorespiration research was made by the use of the
14CO2 isotope to separate
CO2 fluxes into and out of leaves in an open gas
exchange system under steady-state conditions (Ludwig and Canvin,
1971). In these experiments, a leaf is illuminated in
12CO2 until steady state is
reached, and then
14CO2-labeled
CO2 is provided. From the uptake of
14CO2 and the internal
concentrations of 14CO2 and
12CO2 the rates of gross
CO2 assimilation, originating from external CO2 and from re-assimilation, gross
CO2 evolution and re-assimilation were calculated
(Gerbaud and André, 1987; Stuhlfauth et al., 1990).
Some authors use the labeling of the CO2 evolved
after illumination in air containing
14CO2 to calculate
CO2 evolution rates under photorespiratory and non-photorespiratory conditions (Bauwe et al., 1987). These
measurements make it possible to separate the contribution of primary
products and end products to the photorespiratory as well as to the
respiratory CO2 release (Pärnik and
Keerberg, 1995).
The determination of carboxylation and oxygenation rates of Rubisco
from fluorescence measurements, CO2 gas exchange,
and Rubisco kinetics has been described by Laisk and Sumberg (1994). This method can be used to calculate not only the rates of
CO2 assimilation and photorespiration but also
the rate of mitochondrial respiration in the light (Laisk and Loreto,
1996). For this, the plastidic CO2 concentration
and the CO2 transport resistance in mesophyll
cells are required.
To address the problem of sources and sinks for
CO2 and O2 in plants, we
present a new method, based on considerations from Gerbaud and
André (1987), using
13CO2 and mass spectrometry
to determine CO2 fluxes under conditions of
steady-state photosynthesis. The method was used to determine the rates
of net CO2 uptake, gross
CO2 assimilation, photorespiratory CO2 release, and mitochondrial respiratory
CO2 evolution in the light by attached leaves of
tomato under different light intensities and at varying drought stresses.
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RESULTS |
Signal Curve Characteristics
In Figure 1, the mass spectrometric
signal curves for 12CO2 and
13CO2 after switching from
the gas stream containing
12CO2 to the gas stream
containing 13CO2 with an
empty cuvette and with a leaf in the cuvette in the dark or in the
light, respectively, are shown. The
13CO2 signal rises while
the 12CO2 signal falls. The
13CO2 concentration reached
after switching to 13CO2
with a leaf in the dark (II) is the same as without a leaf in the
cuvette (I), because no CO2 fixation occurs in
the dark and no 13CO2 is
released from the plant.
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Figure 1.
Mass-spectrometric signal curves of
12CO2 and
13CO2 after switching to
the gas stream containing
13CO2 and no
12CO2 with an empty cuvette
(I, IV) and with a leaf in the cuvette in the dark (II, V) or during
photosynthetic steady state (III, VI) under a light intensity of 850 µmol photons m 2 s1.
The system was provided with a gas stream containing
12CO2 prior to application
of 13CO2 (gas flow 50 L
h1, 350 µL L1
CO2, 210 mL L1
O2, 70% relative humidity, 23°C). The
assimilation of 13CO2 by
the leaf (A13C) and the release of
12CO2 from the leaf in the
light (R12C) are used to determine the
intercellular 13CO2 and
12CO2 concentration,
respectively, and to determine true CO2
assimilation. The curves were smoothed with a quadratic Savitzky-Golay
function using an appropriate software (HP ChemStationDataAnalysis,
Hewlett-Packard) and transferred to the same time axis (switching to
13CO2 at t = 0 including 2 s of response time). For further details see
"Results" and "Discussion."
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The illuminated leaf (III) takes up
13CO2 without releasing
13CO2 for almost the first
20 s (Ludwig and Canvin, 1971) so that the
13CO2 concentration in
the gas stream with a leaf in the cuvette is lower than the
maximal 13CO2
concentration, which is reached when switching to
13CO2 is
repeated without a leaf in the cuvette. This
maximal 13CO2
concentration is reached in less than 20 s (12 s for a gas flow
rate of 50 L h1) after switching to
13CO2. The fact that the
13CO2 curves with a
darkened leaf, without a leaf, and with a filter paper in the cuvette
(not shown) are identical confirms that the presence of a leaf in the
cuvette does not affect the gas flow characteristics and that the
signals without a leaf can serve as reference for the calculations of
13CO2 uptake or
12CO2 evolution.
The 12CO2 concentration
reached with a darkened leaf (V) is higher than without a leaf (IV)
because 12CO2 is generated
from dark respiration. The
12CO2 signal with an
illuminated leaf (VI) is again higher because in the light
12CO2 is evolved out of the
photorespiratory pathway and from mitochondrial respiration.
Exposing the illuminated leaf to
13CO2 up to 20 min
results in a slight but continuous increase of the
13CO2 signal (data not
shown). Because of the ongoing labeling of photosynthetic and
photorespiratory intermediates
13CO2 is
released from the leaf and the visible uptake of
13CO2 gets smaller. After
20 min no apparent increase in the
13CO2 signal occurs any
longer, and the rate of net
13CO2 uptake calculated at
this point of time is higher than the net
12CO2-uptake rate (A)
measured before switching to
13CO2. A reason for this
might be an incomplete labeling of intermediates of the glycolate
pathway, as the evolved CO2 does not become
labeled completely, although the signal for
12CO2 release decreases
because part of the evolved CO2 is released as
13CO2.
Figure 2 shows the original mass
spectrometric signal curves for
12CO2 with and without a
leaf in the cuvette after providing 3,000 µL L1
13CO2 at photosynthetic steady state.
Flushing the gas exchange system with
13CO2 leads to a decrease
of the 12CO2
concentration from 3,000 µL L1 to
nearly 25 µL L1. Within 12 s a
difference between the
12CO2 concentrations with
and without a leaf in the cuvette can be observed. The
12CO2 concentration is
higher with a leaf because of mitochondrial 12CO2 release. From this
gross CO2 evolution out of the leaf mitochondrial respiration can be calculated.
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Figure 2.
Mass spectrometric signal curves for
12CO2 after switching to
the gas stream containing 3,000 µL L1
13CO2 and no
12CO2 without and with an
illuminated leaf (850 µmol m2
s1) in the cuvette. The system was provided
with a gas stream containing
12CO2 prior to application
of 13CO2 (gas flow 50 L
h1, 3,000 µL L1
CO2, 210 mL L1
O2, 70% relative humidity, 23°C). The curves
were not smoothed but transferred to the same time axis (switching to
13CO2 at t = 0 including 2 s of response time). The difference between the
curves at t = 12 s was used to calculate the
evolution of CO2 by mitochondrial respiration in
the light.
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The rates of net CO2 uptake, gross
CO2 assimilation, and gross
CO2 evolution measured with the new mass
spectrometric isotope technique change typically in relation to the
ambient CO2 and O2
concentration (data not shown). This shows the validity of the new method.
Effect of Light Intensity and Water Deficit on Steady-State Net
CO2 Uptake, Gross CO2 Assimilation, and Gross
CO2 Evolution
The rates of net CO2 uptake (A), gross
CO2 assimilation (TPS), gross
CO2 evolution (RC),
mitochondrial respiration (Resp), and photorespiration (PR) were
measured at photosynthetic steady state on control and drought-stressed
tomato leaves under different light intensities.
When the light intensity is increased from 90 to 850 µmol photons
m2 s1 A and TPS rise
2.5-fold in control and weakly stressed plants (Fig.
3) because more light-generated ATP and
NADPH are available for CO2 fixation in the
Calvin cycle. Lowering the leaf water potential from  0.6 MPa in
controls to 1.8 MPa in severely stressed plants leads to a decrease
of transpiration and leaf conductance (Haupt-Herting, 2000). This
results in an internal CO2 concentration of 112 µL L1 in severely stressed plants compared
with 227 µL L1 in controls under saturating
light intensities and A and TPS decrease by 82% and 72%,
respectively. Severely stressed plants seem to be widely unaffected by
light intensity. This means that CO2 fixation
under drought stress is not limited by light absorption but by internal
CO2 deficiency because of stomatal closure or by
non-stomatal effects like inhibition of ATP synthase, photosystem II
efficiency, or Rubisco activity (Cornic, 1994; Lawlor, 1995). In
severely stressed tomato plants the specific activity of Rubisco, measured as 14C-incorporation into acid-stabile
compounds, decreases to less than one-half of the activity measured in
controls (Haupt-Herting, 2000).
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Figure 3.
Rates of steady-state net
CO2 uptake (A,  ), gross
CO2 assimilation (TPS,  ), and gross
CO2 evolution (RC,
 ) of attached leaves of tomato at three different light intensities
in relation to leaf water potential. Measurements were taken in an
open gas exchange system using a mass spectrometric
13CO2 isotope technique.
Leaves were provided with air (gas flow 50 L
h1) containing 210 mL
L1 O2, and 350 µL
L1 12CO2 or
13CO2, respectively, at
70% relative humidity and 23°C. Points are means of at least six
replicates; SE  10%.
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RC, which consists of the
CO2 released from photorespiration and
mitochondrial respiration, is stimulated by increasing light intensities from 2.0 µmol CO2
m2 s1 under low light
to 3.7 µmol CO2 m2
s1 under saturating light in
control plants and from 1.1 µmol CO2 m2 s1 to 2.0 µmol
CO2 m2
s1 in severely stressed plants (Fig.
4). Severe drought stress (1.8 MPa)
results in a decrease of RC of
approximately 47% under high light, which is smaller than the relative
decrease of TPS (72%).
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Figure 4.
Rates of steady-state gross
CO2 evolution (RC,
), photorespiration (PR,  ), and mitochondrial respiration (Resp,
X) of attached leaves of tomato at three different light intensities in
relation to leaf water potential. Measurements were taken in an open
gas exchange system using a mass spectrometric
13CO2 isotope technique.
Leaves were provided with air (gas flow 50 L
h1) containing 210 mL
L1 O2 at 70% relative
humidity and 23°C. The CO2 concentration was
350 µL L1 12CO2 or
13CO2, respectively, for
determination of gross CO2 evolution and 3,000 µL L1 12CO2 or
13CO2, respectively, for
measurement of mitochondrial respiration. Photorespiration is
calculated from RC and Resp. Points are
means of at least six replicates; SE 10%.
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Effect of Light Intensity and Water Deficit on Mitochondrial
Respiration in the Light, Photorespiration, and Re-Assimilation
The rates of mitochondrial respiration in the dark in 350 and 3,000 µL L1 CO2 are
the same in tomato leaves (Haupt-Herting, 2000). Provided that
mitochondrial respiration in the light is not affected by CO2 partial pressure between 350 and 3,000 µL
L1 CO2, Figure 4 shows
the rates of mitochondrial respiration in the light at 3,000 µL
L1 CO2 and the
contribution of mitochondrial respiration and photorespiration to
RC. Mitochondrial respiration in the light
depends on the incident light intensity (0.82 µmol
CO2 m2
s1 under low and 0.93 µmol
CO2 m2
s1 under high light in control plants) and is
in the same range as respiration in the dark (0.85 µmol
CO2 m2
s1). Also, mitochondrial respiration in the
dark is lower in stressed plants than in controls (data not shown).
Mitochondrial respiration in the light responds to drought stress
with a decrease from 0.93 µmol CO2
m2 s1 in controls to
0.17 µmol CO2 m2
s1 under severe stress (Fig. 4).
The rate of photorespiration is higher than the rate of mitochondrial
respiration and represents the main part
of gross CO2 evolution (Fig. 4). It
depends on light intensity (1.2 µmol
CO2 m2
s1 under low light and 2.8 µmol
CO2 m2
s1 under saturating light for control plants)
and is decreased by drought stress from 2.8 µmol
CO2 m2
s1 in control to 1.8 µmol
CO2 m2
s1 in severely stressed plants under high light
(Fig. 4A). As PR is less inhibited than TPS the ratio of PR to TPS
rises with increasing drought stress in tomato under all light regimes
from 22% in control plants to 39% in severely stressed plants (Fig.
5A), which shows that the oxygenation
reaction of Rubisco is stimulated under drought stress relative to the
carboxylation reaction.
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Figure 5.
A, Ratio of photorespiration (PR) to gross
CO2 assimilation (TPS); B, ratio of
re-assimilation (AR) to TPS in relation to
leaf water potential at 90 (), 400 (), and 850 µmol photons
m2 s1 ( ).
Measurements were taken in an open gas exchange system
using a mass spectrometric
13CO2 isotope technique.
Leaves were provided with air (gas flow 50 L
h1) containing 210 mL
L1 O2 and 350 µL
L1 12CO2 or
13CO2, respectively, at
70% relative humidity and 23°C.
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The CO2 evolved by the glycolate pathway is
available for CO2 assimilation in addition to the
CO2 in the atmosphere and is partly
re-assimilated before leaving the leaf. The relative contribution of
re-assimilation of (photo) respiratory
12CO2
(AR) to gross CO2
assimilation is only slightly affected by light intensity (Fig. 5B). In
control plants, 23% of TPS are due to AR
under low or moderate light and 29% under saturating light. This can
be explained by higher rates of photorespiratory
CO2 evolution under high light conditions. As PR
is less decreased under drought than TPS, the contribution of
AR to TPS rises to over 40% in weakly
stressed plants, 50% in moderately stressed plants, and nearly 60% in
severely stressed plants.
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DISCUSSION |
Critical Assessment of the New Method
The new mass spectrometric
12CO2/13CO2
isotope technique for the determination of accurate
CO2 flux rates into and out of the leaf
is derived from 14CO2
measurements of total stomatal CO2 uptake by
Ludwig and Canvin (1971). The method has been expanded for
re-assimilation calculations by Gerbaud and André (1987) and
Stuhlfauth et al. (1990). The substitution of
14CO2 used in earlier
studies by 13CO2 used here
has some important advantages: The discrimination of Rubisco against
13CO2 (approximately 27 )
is smaller than against
14CO2 (approximately 60;
Farquhar et al., 1982). The radioactive isotope
14CO2 can only be applied
in tracer concentrations of approximately 0.3% of whole
CO2 content of the gas mixture (Stuhlfauth et
al., 1990). So the rates for
14CO2 uptake during
photosynthesis are quite small and the rates of gross
CO2 assimilation and refixation as well as
internal 14CO2
concentration calculated from this might have large errors. The stable
isotope 13CO2, however, can
be used in any concentration necessary, e.g. 3,000 µL L1
13CO2 (and no
12CO2) to suppress
photorespiration. The high signals for
13CO2 uptake
facilitate correct determination of internal
13CO2 concentration,
refixation, and gross CO2 assimilation. In addition, the evolution of
12CO2 through stomata (Fig.
2) and the influence of external conditions on it can directly be
observed, which is impossible at
14CO2 measurements
where 12CO2 uptake
accompanies 12CO2
evolution at high external
12CO2 concentrations.
In contrast to Loreto et al. (1999), who observed the emission of
12CO2 in a
13CO2-atmosphere with a
13CO2-insensitive infrared
gas-analyzer, the mass spectrometric method allows the monitoring of
the 13CO2 signal
in addition to the 12CO2
signal. Therefore, the determination of gross CO2
evolution, gross CO2 assimilation, and
re-assimilation of (photo) respiratory CO2 out of
gas exchange data is possible and it is not necessary to calculate
carboxylation and oxygenation from the electron transport rate, often
detected by fluorescence measurements, and theoretical considerations
of Rubisco kinetics (Di Marco et al., 1994; Laisk and Sumberg, 1994;
Loreto et al., 1994).
For the calculation of re-assimilation rates the determination of
internal CO2 concentrations is necessary.
Therefore, it is essential to measure leaf conductance carefully,
especially under drought stress conditions where transpiration rates
are small. Also, nonuniform stomatal closure, which does not occur in
tomato leaves (not shown), would lead to a failure in
ci calculations (Terashima, 1992) and,
therefore, result in false estimations of refixation.
In addition to intercellular refixation, intracellular refixation may
occur. Gerbaud and André (1987) assume the intracellular refixation of 12CO2 to be
negligible because the carboxylation resistance would be dominant over
the resistance for diffusion to the air space. On the other hand, high
internal or stomatal resistances may favor intracellular
re-assimilation (Laisk and Loreto, 1996), especially under drought
stress. Intracellular re-assimilation, which is not considered by the
method described here, may lead to an underestimation of gross
CO2 assimilation and CO2
evolving reactions the extent of which is unknown.
Mitochondrial Respiration in the Light
It is widely accepted that oxidative phosphorylation occurs in the
light (Sharp et al., 1984; Gerbaud and André, 1987). However, the
magnitude of mitochondrial respiration in the light is still unclear
(Krömer, 1995). In our experiments mitochondrial respiration in
the light, which was determined at high CO2
concentrations, is smaller than photorespiration and almost light
independent (Fig. 4). Light affects the activity of the pyruvate
dehydrogenase complex by a light activated protein kinase. This kinase
depends on the NH3 formed in the glycolate
pathway (Randall et al., 1996). The inhibition of photorespiration by
high CO2 during the measurement of mitochondrial
respiration and, as a consequence, the deficiency in photorespiratory
NH3 might result in less protein kinase activity and, therefore, in the pyruvate dehydrogenase complex being no longer
inactivated in the light. This effect of non-photorespiratory conditions on mitochondrial respiration would also occur if 20 mL
L1 O2 are used to
suppress photorespiration, but under these conditions light inhibition
of mitochondrial respiration has often been observed (Krömer,
1995).
Mitochondrial respiration in the light is inhibited by water deficit in
tomato plants (Fig. 4). According to Laisk and Sumberg (1994), the part
of CO2 evolution in the light that cannot be attributed to the oxygenation reaction is influenced by the internal CO2 concentration. In mitochondrial respiration
dissimilation of not only end products but also primary products occurs
(Pärnik and Keerberg, 1995). Therefore, respiration in the light
may depend on the amount of primary products, which are expected to be
smaller in drought-stressed plants than in controls because of a
decrease in CO2 assimilation. This could be a
reason for lower rates of mitochondrial respiration in the light under
drought stress. Functions of mitochondrial respiration in the light
might be the supply of ATP and carbon skeletons for synthesis reactions
in the cytosol and chloroplast or the oxidation of excess redox
equivalents under light or drought stress (Krömer, 1995).
In this study, high CO2 concentrations were used
to determine mitochondrial respiration in the light under
non-photorespiratory conditions (Fig. 4). However, elevated
CO2 may influence mitochondrial respiration and
the rates at 3,000 µL L1
CO2 may differ from those at 350 µL
L1 CO2. The effect of
high CO2 concentrations on the rate of dark respiration seems to depend on growth conditions and varies in different plant species between 60% of inhibition and 30% of
stimulation (Gonzàles-Meler et al., 1996). The inhibition of dark
respiration could be the result of a direct effect on cytochrome c
oxidase or succinat dehydrogenase (Gonzàles-Meler and Siedow,
1999). In tomato plants, mitochondrial respiration in the dark is not affected by 3,000 µL L1
CO2 compared with 350 µL
L1 CO2 (Haupt-Herting,
2000). This leads to the conclusion that no inhibition of cytochrome c
oxidase or other enzymes occurs. However, it is not yet fully
understood how changes of CO2 assimilation and
inhibition of photorespiration may influence dissimilatory processes.
At high CO2 concentrations, Laisk and Sumberg
(1994) detected carboxylation of a substrate other than RuBP, in
addition to RuBP carboxylation, that may be caused by
phosphoenolpyruvate carboxylase activity. In our respiration
measurements this non-RuBP carboxylation would be included in TPS and
the rate of respiration in the light calculated from this TPS value is
independent from the type of CO2 assimilation.
But mitochondrial respiration in the light determined by the
12CO2/13CO2
technique could be accompanied by CO2 evolution
from the decarboxylation of malate or pyruvate (Laisk and Sumberg,
1994).
Photorespiration and Re-Assimilation of (Photo) Respiratory
CO2
Most studies dealing with the effects of light intensity or
drought stress on photorespiration used
16O2/18O2
mass spectrometry to determine gross O2 uptake,
which is often related to photorespiration without taking mitochondrial
respiration or Mehler reaction into account (Renou et al., 1990;
Tourneux and Peltier, 1995). In our investigations, however, oxygen as well as carbon fluxes have carefully been determined (Haupt-Herting, 2000; Haupt-Herting and Fock, 2000). In control plants of tomato the
rate of photorespiration is 22% of the rate of gross
CO2 assimilation (Figs. 3 and 4). This matches
data of 18O- or
14C-labeling of intermediates of the glycolate
pathway, which proved that photorespiration is 27% of net
photosynthesis at ambient CO2 concentration in
wheat (de Veau and Burris, 1989).
In the experiments presented here, photorespiratory
CO2 release is stimulated by light and rises
relatively to CO2 uptake under drought stress
(Figs. 4 and 5). This is in accordance with earlier results (Thomas and
André, 1982; Tourneux and Peltier, 1995; Biehler and Fock,
1996).
Studies on tomato plants showed that in addition to A and TPS the
activity of photosystem II as well as gross O2
uptake decrease in relation to water deficit (Haupt-Herting and Fock,
2000) and that the reduction of A cannot solely be caused by reduced
internal CO2 concentration. In stressed tomato
plants a greater part of photosynthetic electrons flows to oxygen
rather than to CO2 than in the controls. It
appears that these electrons feed Mehler reaction and the
photosynthetic oxidation cycle.
The CO2 evolved by (photo) respiration is partly
re-assimilated into the Calvin cycle. Drought stress results in a
remarkable increase of the contribution of re-assimilation to gross
CO2 assimilation in tomato plants (Fig. 5).
Corresponding data have been found earlier in Digitalis
lanata (Stuhlfauth et al., 1990). Re-assimilation of
CO2 consumes ATP and reducing equivalents, and
higher rates of re-assimilation under water deficit were interpreted as
contribution to the degradation of excess electrons (Fock et al.,
1992). Also, re-assimilation maintains carbon flux and enzyme substrate
turnover, which helps the plant to recover after rewatering (Stuhlfauth et al., 1990). Thus, photorespiration plays an important role in
protecting plants from photoinhibition by using up excessive photosynthetic electrons in the glycolate pathway and by
re-assimilation of (photo) respiratory
CO2.
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MATERIALS AND METHODS |
Plant Growth and Stress Application
Tomato (Lycopersicon esculentum Mill. cv
Moneymaker; Hild, Marbach, Germany) seeds were sown individually in
small pots of compost (ED 73, Einheitserdenwerk, Hameln, Germany) and
then transferred to 2.5-L pots with a mixture of 10% sand in potting
compost 7 d after germination. Plants were grown in a growth
chamber under weak light (200 µmol photons m2
s1) during a 16-h-light period with 23°C in the light
and 17°C in the dark with a constant relative air humidity of 70%.
Plants were watered daily and regularly supplied with a commercial
nutrient solution (Flori 3, Planta Düngemittel, Regenstauf,
Germany). The youngest, fully expanded leaf (normally the fifth leaf
from the top) of 5-week-old plants was used. Leaves of well watered plants then showed a leaf water potential of 0.6 MPa measured according to Scholander et al. (1965) with a pressure bomb (self constructed, Metallwerkstätten der Universität,
Kaiserslautern, Germany). To induce an almost natural, reversible
drought stress allowing the plant enough time to acclimate, irrigation
was stopped 2, 5, or 8 d before measurements were taken. These
treatments resulted in weak (leaf water potential 0.9 MPa), moderate
(1.3 MPa), or severe water stress (1.8 MPa). Even severely stressed plants showed complete recovery of leaf water potential, transpiration, and net photosynthesis after rewatering.
The CO2 Isotope Fluxes in Illuminated Leaves
To determine true CO2 assimilation,
photorespiration, and mitochondrial respiration in the light in
attached leaves, we use 13CO2 and mass
spectrometry to measure the 13CO2 flux into and
the 12CO2 flux out of an illuminated leaf.
Figure 6 shows the fluxes of
13CO2 and 12CO2 into
and out of an illuminated leaf, respectively. The
13CO2 isotope provided in the atmosphere (e.g.
350 µL L1 pure 13CO2 and no
12CO2) is taken up into the intercellular space
and the mesophyll cells to be assimilated in the Calvin cycle, which is
located in the chloroplasts. The 13CO2 isotope
is not evolved by photorespiration or mitochondrial respiration after
internal cycling through primary products for the first 20 to 30 s
(Ludwig and Canvin, 1971; Gerbaud and André, 1987; Pärnik
and Keerberg, 1995). Therefore, net 13CO2
uptake equals gross 13CO2 uptake
(A13C) for the first 20 s after
switching to 13CO2. Photorespiration and
mitochondrial respiration release 12CO2 into
the intercellular space (RC). A part of this
12CO2 is re-assimilated in the Calvin cycle
(AR), whereas the other part is evolved into
the atmosphere. Because the 12CO2 concentration
is in the atmosphere and, therefore, 12CO2
uptake is very small, net 12CO2 evolution
(R12C) can be registered outside the leaf.
Refixation of 12CO2 occurs corresponding to the
fixation rate of 13CO2 and depends on the ratio
of the internal concentrations of 12CO2 to
13CO2. The discrimination of
13CO2 is small (27; Farquhar et al., 1982)
and needs not be taken into account.
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|
Figure 6.
Scheme of CO2 fluxes into
and out of an illuminated leaf provided with
13CO2 in the atmosphere.
The fluxes of 13CO2 and
12CO2 measurable outside
the leaf (gross 13CO2
uptake A13C;
12CO2 release
R12C) and the assumed fluxes inside the
leaf (gross 12CO2 release
RC;
12CO2 re-assimilation
AR) are shown. For further details see text
in "Materials and Methods."
|
|
Gas Exchange Measurements
The Open Gas-Exchange System
The rates of net CO2 uptake (A), true photosynthetic
CO2 assimilation (TPS), and gross CO2 release
(RC) by attached leaves were determined at
photosynthetic steady state in an open gas exchange system coupled to a
mass spectrometer (Fig. 7). The
continuous gas stream (50 L h1) passed through a
humidifier and a condenser to achieve a relative air humidity of 70%.
A three-way valve allows the gas stream to be switched between
12CO2 and another gas stream containing the
same concentration of pure 13CO2. The system
contained a thermostated aluminum leaf cuvette illuminated by a halogen
lamp and a thermostated flow chamber (self constructed,
Metallwerkstätten der Universität, Kaiserslautern, Germany)
with a teflon-membrane inlet into a quadrupole mass spectrometer (5970 Series Mass Selective Detector, Hewlett-Packard, Waldbronn, Germany)
where the concentrations of 13CO2
(m/z = 45) and 12CO2
(m/z = 44) in the gas stream were detected
simultaneously and continuously. The diffusion through the
Teflon-membrane and the sensitivity of the mass spectrometer were equal
for both isotopes. No significant drifts in the CO2 signals
occur during the measuring time. The partial pressure of water vapor in
the air was measured with a humidity sensor (HMP 233, Vaisala, Hamburg,
Germany). Leaf temperature was determined with a
copper-constantan-thermocouple in contact with the lower side of the
leaf.
Proceeding of the Gas-Exchange Measurement and CO2 Flux
Calculations
At the beginning of an experiment the mass spectrometric signals
for 12CO2 (350 µL
L1) without a leaf in the cuvette are registered. Then an
attached leaf is placed into the cuvette and illuminated in a
continuous gas stream (50 L h1) containing
12CO2 until photosynthetic steady state is
reached. The rates of net photosynthetic CO2 uptake (A),
transpiration (E), and leaf conductance (gs) are calculated as
previously described (Biehler and Fock, 1996).
At steady-state photosynthesis, a gas mixture containing no
12CO2 but 13CO2 in air
is suddenly supplied to the leaf for 1 min. The rate of
13CO2 assimilation
(A13C) can be calculated from the gas flow
rate (F, [µmol s1]), the difference in
13CO2 concentration with
(13co) and without a leaf
(13ca, [µL L1]) in the
cuvette and the illuminated leaf area (a,
[m2]):
Re-assimilation of released 12CO2
(AR) must be taken into account when
calculating the rate of true CO2 assimilation (Fig. 6). The
12CO2 isotope will be re-assimilated according
to 13CO2 assimilation and the ratio of internal
concentrations of 12CO2 and
13CO2. The rate of re-assimilation of
12CO2 (AR) is then:
The internal concentrations of CO2 can be calculated
from the fluxes of CO2 into or out of the leaf, the
external CO2 concentration, and the leaf conductance (gs)
determined from transpiration measurements:
The internal 13CO2 concentration is
calculated from the 13CO2 flux into the leaf,
whereas the internal 12CO2 concentration is
calculated from the 12CO2 flux out of the leaf
as determined by the mass spectrometer.
The rate of true CO2 assimilation (TPS), which is the sum
of 13CO2 assimilation
(A13C) and 12CO2
re-assimilation (AR), is given by:
and the rate of gross CO2 release
(RC), which is the sum of
photorespiration and mitochondrial respiration, can be written as:
For measurements of mitochondrial respiration in the light the
leaf was provided with 3,000 µL L1 12CO2
(to inhibit photorespiration) until steady state was reached, and then
12CO2 was replaced by the same concentration of
13CO2. RC,
calculated as described above, is then a measure for the rate of
mitochondrial respiration, which is the only reaction pathway releasing
CO2 under these conditions. It is assumed that the rate of
mitochondrial respiration in the light is not affected by
CO2 partial pressures between 350 and 3,000 µL
L1 CO2.
Measurements at different light intensities were done on the same leaf
one after the other beginning with the lowest intensity. It was
carefully checked that no 13CO2 taken up in the
previous measurement was released in the subsequent run. In these
experiments 13CO2 was offered for only 1 min
before the gas mixture containing 12CO2 was
applied again. The ground signal for 13CO2 was
then reached within 2 min and 13CO2 was not
evolved from the leaf.
| |
ACKNOWLEDGMENT |
We thank Dr. David Lawlor (IACR-Rothamsted, Harpenden, UK) for
critically reading the manuscript.
| |
FOOTNOTES |
Received October 9, 2000; returned for revision November 20, 2000; accepted February 1, 2001.
*
Corresponding author; e-mail fock{at}rhrk.uni-kl.de; fax
49-631-205-2600.
| |
LITERATURE CITED |
-
Badger MR
(1985)
Photosynthetic oxygen exchange.
Annu Rev Plant Physiol
36: 27-53[CrossRef][Web of Science]
-
Bauwe H, Keerberg O, Bassüner R, Pärnik T, Bassüner B
(1987)
Reassimilation of carbon dioxide by Flaveria (Asteraceas) species representing different types of photosynthesis.
Planta
172: 214-218[CrossRef][Web of Science]
-
Biehler K, Fock H
(1995)
Estimation of non-cyclic electron transport in vivo of Triticum using chlorophyll fluorescence and mass spectrometric O2 evolution.
J Plant Physiol
145: 422-426
-
Biehler K, Fock H
(1996)
Evidence for the contribution of the Mehler peroxidase reaction in dissipating excess electrons in drought-stressed wheat.
Plant Physiol
112: 265-272[Abstract]
-
Bradford KJ, Hsiao TC
(1982)
Physiological responses to moderate water stress.
In
Lange OL, Nobel PS, Osmond CB, Ziegler H, eds, Encyclopedia of Plant Physiology, Vol. 12B. Springer-Verlag, Berlin, pp 263-324
-
Catzky J, Jarvis PG, Sestak Z
(1971)
Plant photosynthetic production.
In
W Junk, ed, Manual of Methods. N.V. Publishers, The Hague, The Netherlands
-
Cornic G
(1994)
Drought stress and high light effects on leaf photosynthesis.
In
NR Baker, JR Bowyer, eds, Photoinhibition of Photosynthesis. BIOS Scientific Publishers, Oxford, pp 297-313
-
de Veau EJ, Burris JE
(1989)
Photorespiratory rates in wheat and maize as determined by 18O-labeling.
Plant Physiol
90: 500-511[Abstract/Free Full Text]
-
Di Marco G, Iannelli MA, Loreto F
(1994)
Relationship between photosynthesis and photorespiration in field-grown wheat leaves.
Photosynthetica
30: 41-51
-
Farquhar GD, O'Leary MH, Berry JA
(1982)
On the relationship between carbon isotope discrimination and the intercellular carbon dioxide concentration in leaves.
Aust J Plant Physiol
9: 121-137[Web of Science]
-
Fock HP, Biehler K, Stuhlfauth T
(1992)
Use and degradation of light energy in water stressed Digitalis lanata.
Photosynthetica
27: 571-577
-
Gerbaud A, André M
(1987)
An evaluation of the recycling in measurements of photorespiration.
Plant Physiol
83: 933-937[Abstract/Free Full Text]
-
Gonzàles-Meler MA, Ribas-Carbó M, Siedow JN, Drake BG
(1996)
Direct inhibition of plant mitochondrial respiration by elevated CO2.
Plant Physiol
112: 1349-1355[Abstract]
-
Gonzàles-Meler MA, Siedow JN
(1999)
Direct inhibition of mitochondrial respiratory enzymes by elevated CO2: does it matter at the tissue or whole-plant level?
Tree Physiol
19: 253-259[Web of Science][Medline]
-
Haupt-Herting S
(2000)
Nutzung und Entwertung von Lichtenergie in höheren Pflanzen: Die Auswirkungen von Trockenstre
 auf den Primärstoffwechsel von Lycopersicon esculentum und einer high-pigment Mutante. PhD thesis. University of Kaiserlautern, Kaiserslautern, Germany -
Haupt-Herting S, Fock HP
(2000)
Exchange of oxygen and its role in energy dissipation during drought stress in tomato plants.
Physiol Plant
110: 489-495[CrossRef]
-
Jackson WA, Volk RJ
(1970)
Photorespiration.
Annu Rev Plant Physiol
21: 385-432
-
Krömer S
(1995)
Respiration during photosynthesis.
Annu Rev Plant Physiol Plant Mol Biol
46: 45-70[CrossRef][Web of Science]
-
Laisk A, Loreto F
(1996)
Determining photosynthetic parameters from leaf CO2 exchange and chlorophyll fluorescence.
Plant Physiol
110: 903-912[Abstract]
-
Laisk A, Sumberg A
(1994)
Partitioning of the leaf CO2 exchange into components using CO2 exchange and fluorescence measurements.
Plant Physiol
106: 689-695[Abstract]
-
Lawlor DW
(1995)
Effects of water deficit on photosynthesis.
In
N Smirnoff, ed, Environment and Plant Metabolism. BIOS Scientific Publishers, Oxford, pp 129-160
-
Loreto F, Delfine S, Di Marco G
(1999)
Estimation of photorespiratory carbon dioxide recycling during photosynthesis.
Aust J Plant Physiol
26: 733-736[Web of Science]
-
Loreto F, Di Marco G, Tricoli D, Sharkey TD
(1994)
Measurements of mesophyll conductance, photosynthetic electron transport and alternative electron sinks of field grown wheat leaves.
Photos Res
41: 397-403
-
Ludwig JL, Canvin DT
(1971)
An open gas-exchange system for the simultanous measurement of the CO2 and 14CO2 fluxes from leaves.
Can J Bot
49: 1299-1313
-
Pärnik T, Keerberg O
(1995)
Decarboxylation of primary products of photosynthesis at different oxygen concentrations.
J Exp Bot
46: 1439-1447[Abstract/Free Full Text]
-
Randall DD, Miernyk JA, David NR, Gemel J, Luethy MH
(1996)
Regulation of leaf mitochondrial pyruvate dehydrogenase complex activity by reversible phosphorylation.
In
PR Shewry, NG Helford, eds, Protein Phosphorylation in Plants. Clarendon Press, Oxford, pp 87-103
-
Renou JL, Gerbaud A, Just D, André M
(1990)
Differing substomatal and chloroplastic CO2 concentrations in water-stressed wheat.
Planta
182: 415-419[CrossRef][Web of Science]
-
Scholander PF, Hammel HT, Bradstreet ED, Hemmingsen EA
(1965)
Sap pressure in vascular plants.
Science
148: 339-346[Abstract/Free Full Text]
-
Sharp RE, Matthews MA, Boyer JS
(1984)
Kok effect and the quantum yield of photosynthesis.
Plant Physiol
75: 95-101[Abstract/Free Full Text]
-
Sharkey TD, Berry JA, Sage RF
(1988)
Regulation of photosynthetic electron-transport in Phaseolus vulgaris L., as determined by room-temperature chlorophyll a fluorescence.
Plant
176: 415-424
-
Stuhlfauth T, Scheuermann R, Fock HP
(1990)
Light energy dissipation under water stress conditions: contribution of reassimilation and evidence for additional processes.
Plant Physiol
92: 1053-1061[Abstract/Free Full Text]
-
Terashima I
(1992)
Anatomy of non-uniform leaf photosynthesis.
Photosynth Res
31: 195-212
-
Thomas DA, André M
(1982)
The response of oxygen and carbon dioxide exchanges and root activity to short term water stress in soybean.
J Exp Bot
33: 393-405[Abstract/Free Full Text]
-
Tourneux C, Peltier G
(1995)
Effect of water deficit on photosynthetic oxygen exchange measured using 18O2 and mass spectrometry in Solanum tuberosum L. leaf discs.
Planta
195: 570-577[Web of Science]
© 2001 American Society of Plant Physiologists
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TOP
ABSTRACT
INTRODUCTION
