Plant Physiol. (1998) 117: 619-627

Increase in the Quantum Yield of Photoinhibition Contributes to Copper Toxicity in Vivo¹

Eija Pätsikkä, Eva-Mari Aro, and Esa Tyystjärvi^*

Department of Biology, Plant Physiology, and Molecular Biology, University of Turku, FIN-20014 Turku, Finland

	ABSTRACT

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The effect of copper on photoinhibition of photosystem II in vivo was studied in bean (Phaseolus vulgaris L. cv Dufrix). The plants were grown hydroponically in the presence of various concentrations of Cu²⁺ ranging from the optimum 0.3 µM (control) to 15 µM. The copper concentration of leaves varied according to the nutrient medium from a control value of 13 mg kg¹ dry weight to 76 mg kg¹ dry weight. Leaf samples were illuminated in the presence and absence of lincomycin at different light intensities (500-1500 µmol photons m² s¹). Lincomycin prevents the concurrent repair of photoinhibitory damage by blocking chloroplast protein synthesis. The photoinhibitory decrease in the light-saturated rate of O₂ evolution measured from thylakoids isolated from treated leaves correlated well with the decrease in the ratio of variable to maximum fluorescence measured from the leaf discs; therefore, the fluorescence ratio was used as a routine measurement of photoinhibition in vivo. Excess copper was found to affect the equilibrium between photoinhibition and repair, resulting in a decrease in the steady-state concentration of active photosystem II centers of illuminated leaves. This shift in equilibrium apparently resulted from an increase in the quantum yield of photoinhibition (_PI) induced by excess copper. The kinetic pattern of photoinhibition and the independence of _PI on photon flux density were not affected by excess copper. An increase in _PI may contribute substantially to Cu²⁺ toxicity in certain plant species.

	INTRODUCTION

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Cu²⁺ is an essential micronutrient but in excess is toxic for plants. It is a redox-active metal that functions as an enzyme activator and is an important part of prosthetic groups of many enzymes (for review, see Sandmann and Böger, 1983). Copper concentrations in healthy plant tissues range from 5 to 20 mg kg¹ dry weight. In Cu²⁺-rich environments, accumulation of Cu²⁺ in plant tissues depends on the species and cultivar. Cu²⁺ seems to have several sites of action, which vary among plant species. Toxic concentrations of Cu²⁺ inhibit metabolic activity, which leads to suppressed growth and slow development. Most Cu²⁺ ions are immobilized to the cell walls of roots or of mycorrhizal fungi (Kahle, 1993).

When the tolerance mechanisms in the root zone become overloaded, Cu²⁺ is translocated by both the xylem and phloem up to the leaves. Excess Cu²⁺ may replace other metals in metalloproteins or may interact directly with SH groups of proteins (Uribe and Stark, 1982). Cu²⁺-induced free-radical formation may also cause protein damage (for review, see Fernandes and Henriques, 1991; Weckx and Clijsters, 1996). High concentrations of Cu²⁺ may catalyze the formation of the hydroxyl radical from O₂ and H₂O₂. This Cu²⁺-catalyzed Fenton-type reaction takes place mainly in chloroplasts (Sandmann and Böger, 1980). The hydroxyl radical may start the peroxidation of unsaturated membrane lipids and chlorophyll (Sandmann and Böger, 1980), and these inhibitory mechanisms might contribute to the observed inhibition of photosynthetic electron transport by excess Cu²⁺ (Clijsters and Van Assche, 1985).

The role of Cu²⁺ as an inhibitor of photosynthetic electron transport has been studied in vitro. Both the donor (Cedeno-Maldonado and Swader, 1972; Samuelsson and Öquist, 1980; Schröder et al., 1994) and acceptor (Mohanty et al., 1989; Yruela et al., 1992, 1993, 1996a, 1996b; Jegerschöld et al., 1995) sides of PSII have been proposed to be the most sensitive site for Cu²⁺ action. On the donor side, Cu²⁺ is thought to inhibit electron transport to P680, the primary donor of PSII (Schröder et al., 1994). On the acceptor side, Cu²⁺ interactions with the pheophytin-Q_A-Fe²⁺-domain or Cu²⁺-induced modifications in the amino acid or lipid structure close to the Q_A- and Q_B-binding sites have been suggested to cause the inhibition of electron transport (Jegerschöld et al., 1995; Yruela et al., 1996a, 1996b).

Celeno-Maldonado and Swader (1972) noticed that preincubation of chloroplasts in the light enhanced the Cu²⁺-induced inhibition of electron transport, and that PSII was more susceptible to this kind of inhibition than was PSI. The hypothetical acceptor- and donor-side mechanisms of the light-induced inhibition of electron transport, photoinhibition, involve the same domains of attack as Cu²⁺. Both acceptor- and donor-side photoinhibition trigger the D1 polypeptide of the PSII reaction center for degradation (for review, see Aro et al., 1993). The damaged D1 protein is degraded, and the recovery of PSII activity needs de novo synthesis of D1 protein. Photoinhibition occurs at all light intensities (Tyystjärvi and Aro, 1996); therefore, the cycle of PSII photoinhibition, which is followed by degradation, and, finally, resynthesis of the D1 protein, runs constantly in plant cells in the light. If the photoinhibition-repair cycle is allowed to run for some time at a constant light intensity, equilibrium is reached. At equilibrium (steady state), all three reaction rates (photoinhibition, D1 degradation, and D1 synthesis) are equal. Healthy plants are often able to maintain a high steady-state concentration of active PSII under widely varying light intensities. Even if the concentration of active PSII is lowered by high light, the concentration of D1 protein tends to stay fairly constant (Cleland et al., 1990; Kettunen et al., 1991). In the bean (Phaseolus vulgaris L.) plants used in this study the steady-state D1 protein content remained almost constant even in the presence of excess Cu²⁺.

The effect of Cu²⁺ on photoinhibition in vivo has been studied very little. Vavilin et al. (1995) suggest that excess Cu²⁺ may slow the PSII repair cycle in the green alga Chlorella pyrenoidosa, and Ouzounidou et al. (1997) suggest that Cu²⁺ inhibits adaptation to light in maize. In the current study we show that excess Cu²⁺ induces a large increase in the rate constant of photoinhibition in vivo in a higher plant.

	MATERIALS AND METHODS

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Bean (Phaseolus vulgaris L. cv Dufrix) seeds were sown in vermiculite. After 2 weeks the plantlets were moved to a hydroponic nutrient medium (Hoagland and Arnon, 1950) buffered with 2 mM Mes-KOH, pH 5.5. The nutrient medium was supplemented with nine different concentrations of CuSO₄, from 0.3 µM (control) to 15 µM. Nine plants were placed in each container with 5 L of nutrient solution, and the solution was changed twice a week. The plants were grown in a phytotron at 22°C in a 14-h light/2-h twilight/8-h dark rhythm for 2 weeks. The PPFD of the light phase was 250 µmol m² s¹, which was reduced to 50 µmol m² s¹ during the twilight period. Three plants per treatment were used in each individual experiment, and each experiment was repeated at least three times.

Photoinhibitory Treatments and Fluorescence Induction Measurements

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During the experiment, six leaf discs per treatment were punched from the detached leaves every hour and dark adapted for 1 h between moist paper towels before fluorescence induction was measured with a fluorometer (PAM 101, Heinz Walz, Effeltrich, Germany) using fluorescence software (FIP, Q_A-Data, Turku, Finland). We also checked that the O₂ evolution activity did not change during the incubation period if measured from thylakoids isolated from the leaf discs (data not shown). Initial fluorescence was first measured under a dim-red measuring beam, and F_m was then induced with a 9000 µmol m² s¹ white-light pulse (KL-1500 illuminator, Schott, Mainz, Germany). The percentage of photoinhibitory decrease in PSII activity was calculated as 100 × (F_v/F_m[control]  F_v/F_m[treatment])/F_v/F_m(control). The relevance of the fluorescence measurements was checked by measuring O₂ evolution from thylakoids isolated from control and Cu²⁺-treated leaves in the course of the photoinhibitory treatments.

Measurement of O₂ Evolution

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Emission Spectra

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Leaf Absorptivity

Relative Rate of D1-Protein Degradation

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Analysis of Basic Elements

Chlorophyll Determination

Mathematical Modeling

(1)

We assumed that the D1 protein of the photoinhibited PSII center was degraded in a first-order reaction (Tyystjärvi et al., 1994). The following treatment applies only to the lincomycin-treated leaves with no synthesis of the D1 protein; however, we assume that the K_DEG value is the same if protein synthesis is allowed. Equations 2 and 3 describe photoinhibition and degradation of the D1 protein in the presence of lincomycin.

(2)

(3)

In Equations 2 and 3, A, B, and C are the concentrations of active, inhibited, and D1-depleted PSII centers, respectively, and t is time. At the beginning of each photoinhibition experiment, A was set to F_v/F_m of the nonphotoinhibited sample divided by F_v/F_m of the nonphotoinhibited control samples grown without excess Cu²⁺, B was set to 1  A, and C was set to 0. The smallest initial value of A was 0.88. Table I lists the F_v/F_m values used. The model was optimized assuming that Cu²⁺ does not affect K_DEG. Thereafter, the optimization was done by assuming a linear effect of leaf Cu²⁺ content on K_DEG. ModelMaker software (Cherwell Scientific Publishing, Oxford, UK) was used for the optimization.

	RESULTS

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Visible Damage and Copper Concentration of the Leaves

Analysis of basic elements showed that the copper concentration of the second pair of leaves was a sigmoidal function of the Cu²⁺ concentration of the growth medium. The uptake saturated at 4 to 6 µM. The best fit of the experimental data to a logistic sigmoid curve (Fig. 1; see the figure legend for the equation) was later used as an estimate of the copper content.

View larger version (13K): [in this window] [in a new window]   Figure 1. Copper concentration in the second pair of bean leaves after 2 weeks of hydroponic growth at different concentrations of Cu2SO4. The curve represents the best fit (minimum = 11 mg kg1; maximum = 74 mg kg1; k = 1.4 µM1; and ×50 = 2.8 µM) to a logistic sigmoid relationship, [Cu2+](leaf) = minimum + (maximum  minimum)/(1 + ek([Cu2+]medium  ×50)), between the leaf copper concentration and the concentration of Cu2+ in the medium. Dw, Dry weight.

The chlorophyll content of the leaves treated with the highest Cu²⁺concentration was 69% of control (Table I), but the characteristics of the photosystems were similar. Emission spectra measured with 455 nm excitation (Fig. 2) showed that the Cu²⁺ treatments did not affect the ratio of PSII to PSI; the same result was obtained by 435 and 575 nm excitation (data not shown). Cu²⁺ treatment (4 µM) induced a similar decrease in the F_v/F_m ratios of the leaves and in the light-saturated rate of O₂ evolution (expressed per milligram of chlorophyll; Table I). The unchanged ratio of active PSII per unit of chlorophyll indicates that the Cu²⁺ treatment did not induce major changes in the antenna sizes of the photosystems. Based on the measurements of the chlorophyll content of control and Cu²⁺-treated leaves (Table I), and assuming that each PSII center is associated with 210 and each PSI center with 230 chlorophyll molecules and that the ratio of PSII to PSI is 1.2, the copper concentration of 13 to 76 mg kg¹ dry weight equals 10 to 110 copper ions per PSII reaction center. For measurements of antenna sizes and photosystem stoichiometry in higher plants, see Melis (1996).

View larger version (19K): [in this window] [in a new window]   Figure 2. Emission spectra of thylakoids isolated from control (solid line) plants and plants grown with 4 µM (dashed line) or 15 µM Cu2+ (dotted line) measured with a diode-array fiber-optic spectrophotometer at 77 K. The sample volume was 0.1 mL, the chlorophyll concentration was 2.5 µg/mL, and the excitation was 455 nm.

The highest copper concentrations were measured in the roots, where they were 10 to 20 times higher than in the second pair of leaves. The copper concentration per kilogram dry weight had a tendency to decrease with the age of the leaf (data not shown). The concentrations of Fe and Mn in the leaves correlated negatively with the concentration of copper. No differences in the concentrations of other basic elements (Ca, K, Mg, P, S, and Zn) were observed (data not shown).

Effect of Cu²⁺ on Photoinhibition: The Damaging Reaction

View larger version (26K): [in this window] [in a new window]   Figure 3. Photoinhibition and D1 degradation in the leaves of bean plants grown at two different Cu2+ concentrations. The leaves of control plants (A) and plants grown with 4 µM Cu2+ (B) were illuminated at a PPFD of 1000 µmol photons m2 s1 in the presence of lincomycin. The lines show the best fit to the model obtained using data collected from all photoinhibition treatments in the presence of lincomycin. The solid lines indicate the concentration of active PSII centers, measured as 100 × Fv/Fm(sample)Fv/Fm(control) (). The dashed lines represent the number of D1-depleted PSII centers (); the KDEG value is 0.3 h1 in both A and B. Each data point represents the mean of three independent experiments; three leaves from three different plants were used for each experiment, and different experiments were done with plants from different cultivation batches. The error bars indicate SE and are shown only if larger than the symbol.

View larger version (15K): [in this window] [in a new window]   Figure 4. Correlation of O2 evolution activity with the Fv/Fm ratio (r2 = 0.95). O2 evolution was measured from thylakoids isolated after photoinhibition treatments (1000 µmol photons m2 s1) of control leaves () and leaves grown with excess (4 µM) Cu2+ (). Fv/Fm was measured from leaf discs. Each data point represents the mean of three independent experiments. The error bars indicate SE and are shown only if larger than the symbol.

The first-order nature of photoinhibition allowed us to extract K_PI. By measuring in three different light intensities (Fig. 5), it was verified that excess Cu²⁺ did not affect the basic linearity of K_PI as a function of light intensity (Tyystjärvi and Aro, 1996). This linearity allowed us to approximate _PI, which is the probability that a PSII center becomes photoinhibited upon absorbing a photon.

View larger version (13K): [in this window] [in a new window]   Figure 5. KPI in control () and 4 µM Cu2+-treated () bean leaves measured at three different light intensities. Each KPI value was determined from a first-order fit to the results of a similar 4-h photoinhibition experiment as shown in Figure 2. Error bars indicate SE and are shown only if larger than the symbol.

To elucidate an expression for the function G (Eq. 1), leaves with different copper concentrations were illuminated in the presence of lincomycin, and the K_PI values were compared. Excess Cu²⁺ induced an increase in K_PI, and this effect depended linearly on the copper concentration of the leaves (Fig. 6). Function G is thus reduced to a constant factor _PI as follows:

(4)

where _PI is a constant, [Cu]_excess is obtained by subtracting the control value 13 mg kg¹ dry weight from the leaf copper concentration, and I_a is the PPFD absorbed by PSII of the leaf. The excess concentration was used in Equation 4 instead of total copper concentration of the leaf because suboptimal Cu²⁺ concentrations were not tested. The optimized value of _PI is 0.047 kg mg¹ dry weight (Table II), which results in a 3.8-fold increase in K_PI when going from the control Cu²⁺ concentration to 15 µM Cu²⁺ in the growth medium (76 mg kg¹ dry weight in the leaves; Fig. 6).

View larger version (13K): [in this window] [in a new window]   Figure 6. KPI measured at a PPFD of 1000 µmol photons m2 s1, plotted against the copper concentration of the bean leaves. The copper concentrations of the leaves were read from the curve of Figure 1. The KPI values were determined from first-order kinetic analysis of similar experiments as those shown in Figure 2. Each data point represents a KPI value derived from the curve, which includes Fv/Fm data from three independent experiments. The solid line shows the best linear fit. Error bars indicate SE and are shown only if larger than the symbol. DW, Dry weight.

Effect of Excess Copper on the Repair of Photoinhibited PSII

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View larger version (23K): [in this window] [in a new window]   Figure 7. The effect of excess copper on the equilibrium between photoinhibition and repair. The leaves of control plants (A) and plants grown with 4 µM Cu2+ (B) were illuminated at 1000 µmol photons m2 s1 in the absence of lincomycin. The Cu2+ concentrations of the growth media were 0.3 µM (A) and 4 µM (B). The solid lines indicate the concentration of active PSII centers measured with Fv/Fm (), the dashed lines represent the amount of D1-depleted PSII centers (). Each data point represents three independent experiments, three leaves from three different plants were used for each experiment, and different experiments were done with plants from different cultivation batches. The error bars indicate SE and are shown only if larger than the symbol.

To find out whether the decrease in the equilibrium level is entirely caused by the copper-induced increase in _PI, we measured D1-protein degradation during similar 4-h photoinhibitory treatments in the presence and absence of lincomycin. We have earlier shown that degradation of the damaged D1 protein also obeys first-order kinetics when assayed in vitro or in the presence of a chloroplast protein synthesis inhibitor in vivo (Tyystjärvi et al., 1994). When the model was optimized, allowing excess copper to affect the value of K_DEG, the magnitude of the effect was found to be too small to be significant in the limits of accuracy of the D1-protein determinations. The data therefore suggest that after the photoinhibitory loss of PSII activity, the damaged D1 protein was degraded with similar kinetics in control plants and plants grown with excess Cu²⁺ (Fig. 3). If the degradation of the damaged D1 protein is independent of protein synthesis, as suggested by results in cyanobacteria (Kanervo et al., 1993), then the rate-limiting step of the PSII repair cycle in our bean plants was the degradation of the damaged protein, with a half-time of 2 h (K_DEG value of 0.3 h¹; Table II). Figure 7 shows that once the D1 protein is degraded, it is very rapidly replaced by a new copy and, therefore, little loss of D1 protein can be seen in the absence of lincomycin.

	DISCUSSION

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We examined the effect of excess copper on PSII photoinhibition and the repair cycle in vivo using copper concentrations found in plants growing in polluted areas. Although copper accumulated mainly in roots, the copper level of leaves also increased, causing, in addition to enhancement of photoinhibition, chlorosis and necrotic spots in plants growing in the highest concentrations of Cu²⁺ used.

The cycle of photoinhibition and repair of PSII consists of a light-induced loss of active PSII reaction centers, which are subsequently repaired via enzymatic degradation and resynthesis of the D1 protein (for reviews, see Prasil et al., 1992; Aro et al., 1993). The damaging step is a first-order reaction and its quantum yield is independent of light intensity (Tyystjärvi and Aro, 1996). These key kinetic features of the damaging reaction were unaffected by toxic concentrations of copper (Figs. 3 and 5), indicating that the effect of excess copper was simply to speed up the same photoinhibition reaction that occurs in the absence of Cu²⁺ stress. In control leaves, the relationship between K_PI and PPFD was virtually the same in this study as it was when measured in pumpkin in our earlier study (Tyystjärvi and Aro, 1996). PSII is thus equally vulnerable to light-induced damage in bean and pumpkin leaves. Slow degradation of the damaged D1 protein (Fig. 3), reflected by the low value of K_DEG (Table II), seems to be a frequently occurring feature of higher plants grown under low light (Tyystjärvi et al., 1992; Schnettger et al., 1994). It is possible that this slowness is related to phosphorylation of the D1 protein (Aro et al., 1992).

Simple enhancement of photoinhibition by excess Cu²⁺ may be restricted to physiologically relevant concentrations. In vitro experiments suggest that illumination in the presence of very high Cu²⁺ concentrations induces a light-dependent inactivation mechanism different from that functioning in the absence of excess Cu²⁺ (Jegerschöld et al., 1995; Yruela et al., 1996b). In the present study, leaf Cu²⁺ concentrations were 10 to 110 Cu²⁺ ions per PSII reaction center, whereas concentrations far above 250 Cu²⁺ ions per PSII reaction center have been used in vitro (Jegerschöld et al., 1995; Yruela et al., 1996b).

Copper might cause an increase in _PI in two ways: (a) the metal ion may directly participate in the damaging reaction, e.g. by enhancing the production of hydroxyl radicals (Sandmann and Böger, 1980; Yruela et al., 1996b) or chlorophyll triplets (Sandmann and Böger, 1980); or (b) the toxic metal may block a protective reaction or induce a change in the structure of photosynthetic membranes or proteins (DeVos et al., 1989; Weckx et al., 1996), thereby inducing an increase in _PI, without taking part in the damaging reaction itself. Indeed, Ouzounidou et al. (1997) suggest that excess Cu²⁺ inhibits the process of light adaptation in intact leaves. The data presented here cannot unequivocally distinguish between these two possibilities. However, the protective mechanisms are expected to be induced upon saturation of photosynthesis (Demmig-Adams and Adams, 1996), whereas _PI was independent of light intensity both in the presence and in the absence of excess copper. This finding suggests that copper directly enhances the damaging reaction.

Elucidation of the mechanism by which copper speeds up photoinhibition is hampered by the fact that the mechanism of photoinhibition is unknown in vivo. Two main hypotheses on the molecular mechanism of photoinhibition have been put forward. The acceptor-side mechanism (Vass et al., 1992) depends on accumulation of double-reduced Q_A, and would therefore be enhanced by a Cu²⁺-induced inhibition of electron transfer from Q_A to Q_B (Yruela et al., 1991, 1992). However, the acceptor-side mechanism probably is not the mechanism of photoinhibition in vivo (Tyystjärvi and Aro, 1996). On the other hand, Cu²⁺-induced enhancement of donor-side inhibition would be conceivable, since excess Cu²⁺ inhibits electron donation from water to PSII (Schröder et al., 1994; Jegerschöld et al., 1995). An argument against this mechanism is that donor-side inhibition proceeds in the absence of O₂, and O₂ has been shown to affect photoinhibition in vivo (Van Wijk and Krause, 1992; Leitsch et al., 1994). Donor-side-induced inhibition of PSII was seen when a huge Cu²⁺ concentration was used in vitro (Jegerschöld et al., 1995).

The effect of copper on _PI was linear in the range of 10 to 110 copper ions per PSII, suggesting that the copper effect is caused by free copper ions or binding of copper to one binding site in PSII. The copper concentrations of chloroplasts may also differ from the overall concentrations in the leaves.

In an earlier in vivo study, only a minor excess of Cu²⁺ in the growth medium of the green alga Chlorella pyrenoidosa was found to inhibit the recovery from photoinhibition without affecting the rate of the damaging step (Vavilin et al., 1995). Our results show that in a higher plant excess copper has a major effect on the damaging reaction, but we also addressed the question of whether copper has additional, physiologically important effects on the repair mechanism.

Figure 8 summarizes our findings on the effect of excess copper on photoinhibition in vivo. Our results suggest that the copper-induced decrease in the equilibrium level of active PSII is mainly caused by an increase in _PI.

View larger version (23K): [in this window] [in a new window]   Figure 8. Model of the effect of copper on the repair cycle of photoinhibition. In the presence of lincomycin the behavior of the model (without copper effects) is determined by Equations 2 and 3.

The repair of PSII after photoinhibition starts with degradation of the damaged D1 protein. The resolution of the D1 data does not allow strong conclusions, but it is clear that the D1 protein of the photoinhibited PSII centers was degraded in both Cu²⁺-treated and control plants (Fig. 3), and the data do not suggest any retardation of the degradation reaction by excess copper. This result is in contrast with the in vitro results of Yruela et al. (1996b), which essentially showed that the Cu²⁺-induced enhancement of photoinhibition was not accompanied by enhanced degradation of the D1 protein.

The effects on D1-protein synthesis are not directly accessible from our data because no good mathematical model is available and because PSII heterogeneity may further complicate the cycle (Melis, 1991) from the simple model shown in Figure 8. A feedback mechanism in D1 synthesis of cyanobacteria has been suggested (Tyystjärvi et al., 1996), and in higher plants, D1-protein synthesis is adjusted to match the rate of the photoinhibition-induced degradation (Kettunen et al., 1997). The constancy of the level of D1 protein in photoinhibition experiments both in the presence and absence of excess copper (Fig. 7) suggests that neither the synthesis rate of the D1 protein nor the feedback mechanism is significantly affected by the Cu²⁺ treatments.

Plants can be divided into three categories according to their reaction to excess Cu²⁺ (Baker, 1981): an average plant such as bean is of the "indicator" type and takes up metal ions at a linear rate according to the amount of metal ions in the soil; "excluders" are able to keep the metal ions outside of the roots (DeVos et al., 1991); and a few grasses are Cu²⁺-tolerant "accumulators" or metallophytes (Ernst et al., 1992). Trees usually accumulate heavy metals in their roots (Kahle, 1993), and indeed, our preliminary experiments on birch have shown that under hydroponic growth conditions, translocation of excess Cu²⁺ to leaves is very slow, and Cu²⁺-induced damage is mainly targeted to roots (E. Pätsikkä, E. Tyystjärvi, and E.-M. Aro, unpublished results).

It is obvious that no single mechanism can explain everything about copper toxicity in plants. Photoinhibition is a universal cost factor decreasing the overall yield of photosynthesis, and both in vitro (Mohanty et al., 1989; Yruela et al., 1996b) and in vivo evidence (this study) suggests that excess copper speeds up photoinhibition. Like some other environmental constraints such as low temperature, excess copper displaces the equilibrium between photoinhibition and recovery reactions toward a more inhibited state, enhancing the adverse effects of light. Earlier results from a green alga and maize (Vavilin et al., 1995; Ouzounidou et al., 1997) suggest that such displacement may occur in different ways in different photosynthetic organisms. This behavior suggests that photoinhibition may contribute significantly to copper toxicity in indicator-type species.

	FOOTNOTES

   Received December 1, 1997; accepted March 16, 1998.

	ABBREVIATIONS

Abbreviations: F_m, maximal fluorescence. F_v, variable fluorescence. F_v/F_m, ratio of variable to maximal fluorescence. _PI, quantum yield of photoinhibition. G, relationship between leaf copper concentration and the reaction rate constant of photoinhibition . I_a, photon flux density absorbed by PSII of the leaf. K_DEG, reaction rate constant of D1-protein degradation. K_PI, reaction rate constant of photoinhibition. Q_A and Q_B, primary and secondary electron-accepting plastoquinones of PSII. _PI, effect of leaf copper concentration on K_PI.

	ACKNOWLEDGMENT

We thank Hannu Raitio from the Finnish Forest Research Institute at Parkano station for friendly, flexible, and valuable services concerning the analysis of basic elements.

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