Antioxidative Defense System, Pigment Composition, and Photosynthetic Efficiency in Two Wheat Cultivars Subjected to Drought

doi:10.1104/pp.119.3.1091

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Antioxidative Defense System, Pigment Composition, and Photosynthetic Efficiency in Two Wheat Cultivars Subjected to Drought¹

Barbara Loggini, Andrea Scartazza, Enrico Brugnoli, and Flavia Navari-Izzo^*

Dipartimento di Chimica e Biotecnologie Agrarie, Università degli Studi di Pisa, 56124 Pisa, Italy (B.L., F.N.-I.); and Consiglio Nazionale delle Ricerche, Istituto per l'Agroselvicoltura, 05010 Porano (TR), Italy (A.S., E.B.)

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

We analyzed antioxidative defenses, photosynthesis, and pigments (especially xanthophyll-cycle components) in two wheat (Triticumdurum Desf.) cultivars, Adamello and Ofanto, during dehydrationand rehydration to determine the difference in their sensitivitiesto drought and to elucidate the role of different protective mechanismsagainst oxidative stress. Drought caused a more pronounced inhibitionin growth and photosynthetic rates in the more sensitive cv Adamellocompared with the relatively tolerant cv Ofanto. During dehydrationthe glutathione content decreased in both wheat cultivars, butonly cv Adamello showed a significant increase in glutathionereductase and hydrogen peroxide-glutathione peroxidase activities.The activation states of two sulfhydryl-containing chloroplastenzymes, NADP⁺-dependent glyceraldehyde-3-phosphate dehydrogenase and fructose-1,6-bisphosphatase,were maintained at control levels during dehydration and rehydrationin both cultivars. This indicates that the defense systems involvedare efficient in the protection of sulfhydryl groups against oxidation.Drought did not cause significant effects on lipid peroxidation.Upon dehydration, a decline in chlorophyll a, lutein, neoxanthin,and $beta$ -carotene contents, and an increase in the pool of de-epoxidizedxanthophyll-cycle components (i.e. zeaxanthin and antheraxanthin),were evident only in cv Adamello. Accordingly, after exposureto drought, cv Adamello showed a larger reduction in the actualphotosystem II photochemical efficiency and a higher increasein nonradiative energy dissipation than cv Ofanto. Although differencesin zeaxanthin content were not sufficient to explain the differencein drought tolerance between the two cultivars, zeaxanthin formationmay be relevant in avoiding irreversible damage to photosystemII in the more sensitive cultivar.

INTRODUCTION

Top
Abstract
Introduction
Methods
Results
Discussion
References

A consequence of the drought-induced limitation of photosynthesis is the exposure of plants to excess energy, which, if notsafely dissipated, may be harmful to PSII because of overreductionof reaction centers (Demmig-Adams and Adams, 1992) and increasedproduction of reactive oxygen species in the chloroplasts (Smirnoff,1993).

To counteract the toxicity of active oxygen species, a highly efficient antioxidative defense system, including both nonenzymicand enzymic constituents, is present in plant cells. A relevantdefense system is represented by glutathione, which protects manycellular components and the thiol status of proteins against oxidativestress (Gilbert et al., 1990). GSH may also metabolize hydrogenperoxide by participating in the ascorbate/glutathione cycle orin the reaction catalyzed by GP (EC 1.11.1.9) (Drotar et al.,1985). Hydrogen peroxide is especially toxic in the chloroplastsbecause even at low concentrations it inhibits the Calvin- cycleenzymes possessing exposed sulfhydryl groups, such as G3PDH (EC1.2.1.13) and FBPase (EC 3.1.3.11), hence reducing the photosyntheticcarbon dioxide assimilation (Takeda et al., 1995). The glutathionesystem is efficient provided that GSSH is rapidly reduced to GSHby GR (EC 1.6.4.2). Furthermore, GP and GT (EC 2.5.1.18) reduceorganic peroxides, thus protecting cell proteins and membranesfrom oxidation (Bartling et al., 1993; Navari-Izzo and Izzo, 1994).

It is now well documented that carotenoids are involved in the protection of the photosynthetic apparatus against photoinhibitorydamage by singlet oxygen (¹O₂), which is produced by the excited triplet state of chlorophyll.Carotenoids can directly deactivate ¹O₂ and can also quench the excited triplet state of chlorophyll,thus indirectly reducing the formation of ¹O₂ species (Sieferman-Harms, 1987; Foyer and Harbinson, 1994).On the other hand, it is now widely accepted that zeaxanthin isinvolved in the de-excitation of excess energy via nonradiativedissipation in the pigment bed (Demmig-Adams and Adams, 1992).This process is associated with the de-epoxidation of violaxanthinto zeaxanthin and with the development of a transthylakoidal $Delta$ pH.There is increasing evidence that zeaxanthin, and perhaps theintermediate antheraxanthin, may be responsible for the developmentof nonradiative energy dissipation (Demmig-Adams and Adams, 1992;Pfündel and Bilger, 1994; Horton et al., 1996; Gilmore, 1997;Niyogi et al., 1998).

Among crop plants, durum wheat (Triticum durum), which is often grown in water-limited conditions, is an attractive studysystem because of the natural genetic variations in traits relatedto drought tolerance (Labhilili et al., 1995).

The objective of this study was to investigate possible mechanisms responsible for differential drought tolerance in two wheatcultivars, Adamello and Ofanto. The effects of drought were studiedto elucidate the mechanisms that confer protection from oxidativestress and photoinhibition and to analyze the recovery after rehydration.For these purposes we studied the hydrogen peroxide content andthe glutathione system upon dehydration and rehydration. We alsotested the hypothesis that GSH may protect the sulfhydryl groupsof proteins, as was previously found in Boea hygroscopica (Navari-Izzoet al., 1997), by monitoring the activities of the chloroplastsulfhydryl enzymes G3PDH and FBPase. The effects of dehydrationon photosynthetic efficiency, energy utilization and dissipation,and pigment composition were also studied. Special emphasis wasgiven to the role of zeaxanthin in photoprotection under conditionsof drought.

	MATERIALS AND METHODS

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Plant Material

Seedlings of two durum wheat (Triticum durum Desf.) cultivars, Adamello, which is more sensitive to drought, and Ofanto, whichis less sensitive to drought (Quartacci et al., 1995

), were grownunder fully irrigated conditions and under drought conditions.Seeds were provided by the Istituto Sperimentale per la Cerealicoltura(Foggia, Italy).

Wheat seedlings were grown in 10-L pots containing a mixture of garden soil and sand (1:1, v/v) from January to March in agreenhouse. The mean daily fluence on the upper leaves was 38mol photons m², with the peak of PPFD around 1700 µmol m² s¹. The mean air temperature was 10°C and the mean RH was 70%. Startingfrom 30 d after sowing, two watering treatments were applied:one group of plants was continuously maintained under optimalirrigation (control) and a second group was subjected to droughtby omitting irrigation for 35 d (until 65 d after sowing). Subsequently,droughted plants were re-irrigated for 4 d and the recovery wasstudied. Plants were harvested at 65, 66, and 69 d after sowing.Plants were harvested and samples were collected at 9 AM, witha PPFD of about 200 µmol m² s¹. Roots and shoots were separated, the fresh weights of shootswere recorded, and samples were taken for dry weight measurementsand pigment analysis. Plants (30 for each treatment) were randomlycollected. $Psi$ _w was determined on leaves using a pressure chamber.

Hydrogen Peroxide Determination

Hydrogen peroxide concentration was evaluated as described by Sgherri et al. (1994a)

. This method is very sensitive and reproducible,and excludes the interference of other peroxides (except for asmall effect of lipid peroxide). A standard curve in the 0- to350-µM range was used.

GSH and GSSH

Fresh leaf tissue (0.5 g) was homogenized in ice-cold 5% sulfosalicylic acid (w/v), centrifuged at 12,100g for 15 min, andthe supernatant was used for total and GSSH determinations bythe 5,5 $'$ -dithio-bis-(2-nitrobenzoic acid)/GSSH reductase recyclingprocedure, as described previously (Sgherri and Navari-Izzo, 1995

).GSSH was determined after removal of GSH by 2-vinylpyridine derivatizations.Changes in absorbance of the reaction mixture were measured at412 nm at 25°C, and the contents of total glutathione and GSSHwere calculated as previously described (Sgherri et al., 1994b

).GSH was determined by subtraction of GSSH (as GSH equivalents)from the total glutathione content.

Enzyme Extraction and Activity Determination

The overall procedure was carried out at 0°C to 4°C. Leaf tissue was ground in a chilled mortar using different specific buffersand pH values for each enzyme. Homogenates were squeezed throughtwo layers of muslin, and centrifuged at 12,100g for 20 min. Supernatantsobtained were used for enzyme determination. Conditions for allassays were chosen so that the rate of reaction was constant forthe entire experimental period and proportional to the amountof enzyme added. Proteins were determined according to the methodof Bensadoun and Weinstein (1976)

, using BSA as a standard.

The extraction buffer was 100 mM potassium phosphate, pH 7.0, containing 1 mM Na₂EDTA and 4% (w/v) Polyclar AT (BDH ChemicalsLtd., Poole, UK). The GT activities were assayed as previouslydescribed (Navari-Izzo and Izzo, 1994

). The formation of the conjugatebetween GSH and 1-chloro-2,4-dinitrobenzene was monitored at 340nm, and the activity was calculated using an extinction coefficientof the conjugate of 9.6 mM¹ cm¹.

Extraction of GP was with the same extraction buffer used for GTs. The GP activity was assayed according to the method describedby Navari-Izzo et al. (1997)

, but modified by using lower peroxideconcentrations (0.22 mM). Reaction was initiated by the additionof hydrogen peroxide or t-butyl hydroperoxide, and the decreasein A₃₄₀ was monitored. The enzyme activity was calculated usingthe extinction coefficient of 6.2 mM¹ cm¹. Blank values, obtained without the addition of samples, weresubtracted from the assay values.

Extraction of GR was with the same extraction buffer used for GTs, and its activity was determined following the procedureof Sgherri et al. (1994b)

, measuring the decrease in A₃₄₀ andusing the extinction coefficient of 6.2 mM¹ cm¹. The assay mixture was maintained at 30°C and contained 0.2 Mpotassium phosphate, pH 7.5, 0.2 mM Na₂EDTA, 1.5 mM MgCl₂, 0.25mM GSSH, 25 µM NADPH, and 50 µL of enzyme extract in a 1-mL finalvolume. The reaction was initiated by the addition of NADPH, andcorrections for GSSH-independent NADPH oxidation were not necessary.

G3PDH

Extraction of G3PDH was in 100 mM Tris-HCl, pH 8.1, containing 0.1 mM Na₂EDTA and 4% (w/v) Polyclar AT. To avoid oxidationof the sulfhydryl group, the solution was depleted in oxygen undervacuum and all extractions were carried out under a nitrogen atmosphere.The activity was determined according to the method of Hartenand Eickmeier (1986)

, with slight modifications. The decreasein A₃₄₀ was measured, and the enzyme activity was calculated usingan extinction coefficient of 6.2 mM¹ cm¹. Initial activity was assayed immediately after homogenization.Total activity was assayed on aliquots of enzyme extract incubatedfor 20 min with 20 mM DTT. The assay mixture for initial and totalactivities was maintained at 25°C, and consisted of 100 mM Tris-HCl,pH 8.1, containing 5 mM MgCl₂, 2 mM ATP, 1 mM 3-phosphoglycericacid, 0.06 unit of 3-phosphoglyceric phosphokinase from bakers'yeast (Sigma), 0.14 mM NADPH, and 20 µL of enzyme extract in a1-mL final volume. The reaction was initiated by the additionof NADPH.

Chloroplast FBPase

The extraction and assay conditions utilized were specific for the chloroplastic isoform of the enzyme (Hurry et al., 1995

).The extraction of FBPase was performed in 100 mM Tris-HCl, pH8.0, containing 1 mM Na₂EDTA, 10 mM MgCl₂, and 4% (w/v) PolyclarAT. To avoid oxidation of the sulfhydryl group during the extractionand determination, the same conditions outlined for G3PDH wereused. The activity was determined by monitoring the increase inA₃₄₀ using an extinction coefficient of 6.2 mM¹ cm¹ (Takeda et al., 1995

). Initial activity was assayed immediatelyafter homogenization. Total activity was assayed on aliquots ofenzyme extract incubated for 20 min with 20 mM DTT. The assaymixture for initial and total activities, maintained at 25°C,consisted of 100 mM Tris-HCl, pH 8.0, containing 0.5 mM Na₂EDTA,10 mM MgCl₂, 0.3 mM NADP⁺, 0.6 mM Fru-1,6-bisP, 0.6 unit of Glc-6-P dehydrogenase frombakers' yeast (Sigma), 1.2 units of Glc-P isomerase from bakers'yeast (Sigma), and 100 µL of enzyme extract in a 1-mL final volume.The reaction was initiated by the addition of enzyme extract.

Lipid Extraction and Peroxide Analysis

Leaf tissue was boiled in isopropanol and lipids were extracted immediately, as described by Navari-Izzo et al. (1991)

. Twomilliliters of lipid extract in chloroform was added to a solutionof 5 mL of ethanol, 0.2 mL of 1 M HCl, and 0.1 mL of 1% (w/v)ammonium ferrous sulfate (Droillard et al., 1987

). After 30 s,1 mL of 20% (w/v) ammonium ferrous thiocyanate was added, andthe A₄₈₀ was read 3 min later. A calibration curve with t-butylhydroperoxide (0.6-12 µM) was used for quantification.

Pigment Analysis

Pigment extraction and HPLC analysis were conducted on 0.85-cm² leaf discs taken with a cork borer from fully expanded, exposedleaves, as described by Brugnoli et al. (1994)

. The degree ofde-epoxidation of xanthophyll-cycle components was expressed as(Z+A)/(V+A+Z), where Z is zeaxanthin, A is antheraxanthin, andV is violaxanthin.

Photosynthesis Measurements and Chlorophyll Fluorescence

At the end of the drought period, chlorophyll fluorescence measurements were taken on fully expanded, exposed leaves usinga modulated fluorometer (PAM 101, Walz, Effeltrich, Germany),as previously described (Brugnoli and Björkman, 1992

). Droughtedand control leaves were predarkened for 30 min before startingexperiments. The PPFD of the saturation pulses to determine themaximal fluorescence emission in the presence (F_m $'$ ) and in theabsence (F_m) of quenching on the upper surface of the leaf was9500 µmol m² s¹, whereas the actinic light was 900 µmol m² s¹. The photon yield of PSII ( $Phi$ _PSII) in the light was determinedas $Phi$ _PSII = (F_m $'$ $-$ F)/F_m $'$ (Genty et al., 1989

) after about 45 minof illumination, when steady state was achieved. Stern-Volmernonphotochemical quenching was determined as F_m/F_m $'$ $-$ 1 (Bilgerand Björkman, 1990

). Fluorescence nomenclature is according tovan Kooten and Snel (1990)

Gas-exchange measurements were taken on the same leaves used for fluorescence measurements using an open-flow gas-exchangesystem, as previously reported by Brugnoli and Lauteri (1991).

Statistical Analysis

The significance of differences between mean values obtained from 10 samples produced in three independent experiments wasdetermined by one-way analysis of variance. Fluorescence and gas-exchangeresults are the means of four independent repetitions on differentplants. Comparison among means was performed using the Newman-Keulstest. An analysis of variance test among control values on d 65,66, and 69 showed no significant variation in all of the parametersanalyzed. Therefore, analysis of variance between treatments wasperformed using control data on d 65.

	RESULTS

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Drought conditions induced a slightly larger decrease in $Psi$ _w in the more sensitive cv Adamello than in the more tolerant cvOfanto. However, during rehydration a full recovery of leaf waterstatus was achieved in both cultivars (Table I). Table I alsoshows that cv Adamello plants had a reduction in dry weight followingdehydration. Four days of rehydration were not sufficient to recoverthe growth rate of control cv Adamello plants, whereas cv Ofantoshowed a smaller, insignificant reduction in dry weight.

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Table I. Effects of dehydration and rehydration on $Psi$ _w and growth parameters in the wheat cvs Adamello and Ofanto

Results are the means of 10 repetitions from three independent experiments. SE of the means was always less than 10%. For comparisons between the means, one-way analysis of variance was used. Values in each row followed by different letters are significantly different at P $<=$ 0.01. C, Control; D, drought-stressed; R₁, rehydrated for 1 d; R₂, rehydrated for 4 d.

Drought caused a 30% decrease in GSH+GSSH and GSH contents. Full recovery of these contents could not be achieved after 4d of rehydration in either cultivar (Fig. 1). In plants subjectedto drought, net oxidation of GSH did not occur, as was evidentfrom the lack of significant differences in the GSH/GSSH ratioin cv Ofanto and the increase in this ratio in cv Adamello comparedwith the control (Fig. 1).

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Figure 1. Effects of dehydration and rehydration on GSSH and GSH contents in the wheat cvs Adamello and Ofanto. Bars represent the SE (n = 10 repetitions from three independent experiments). One-way analysis of variance was used for comparisons between the means. Bars with different letters are significantly different at P $<=$ 0.01.

In cv Adamello the GR and hydrogen peroxide-GP activities increased in stressed plants, reaching 136% and 200% of the control,respectively; however, after 1 d of rehydration the activitiesof these enzymes recovered and were not significantly differentfrom those of the control (Table II). In cv Ofanto drought didnot cause changes in the specific activities of GR and GP (TableII), whereas the specific activity of GTs was about 80% of thecontrol value after 1 d of rehydration (Table II). Lipid peroxidecontents did not change during dehydration and rehydration ineither cultivar (Table II).

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Table II. Effects of dehydration and rehydration on GR, GTs, and GP activities (nkat/mg protein) and lipid peroxides (nmol/mg dry weight) in the wheat cvs Adamello and Ofanto

Results are the means of 10 repetitions from three independent experiments. SE of the means was less than 10%. For comparisons between the means, one-way analysis of variance was used. Values in each row followed by different letters are significantly different at P $<=$ 0.01. C, Control; D, drought-stressed; R₁, rehydrated for 1 d; R₂, rehydrated for 4 d; BUT, butyl hydroperoxide.

According to the trend of hydrogen peroxide-GP activity, the hydrogen peroxide content (Fig. 2) showed significant changesonly in cv Adamello, with a decrease of about 50% compared withcontrol during drought, and with a partial recovery of 80% ofthe control value in plants rehydrated for 4 d.

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Figure 2. Effects of dehydration and rehydration on hydrogen peroxide content in the wheat cvs Adamello and Ofanto. Bars represent the SE (n = 10 repetitions from three independent experiments). One-way analysis of variance was used for comparisons between the means. Bars with different letters are significantly different at P $<=$ 0.01.

The sulfhydryl plus disulfide groups, sulfhydryl levels, and percentage of sulfhydryl groups of soluble and membrane proteinsdid not show significant variations during dehydration and rehydrationin either cultivar (data not shown).

The activity of G3PDH was significantly affected by drought in cv Ofanto but not in cv Adamello. In drought-stressed and rehydratedcv Ofanto leaves the total activity was about 70% to 80% of thecontrol value, whereas the initial activity was maintained atcontrol levels. However, in drought-stressed plants the activationstate of this enzyme (percentage of initial activity on totalactivity) did not change (Fig. 3). On the contrary, FBPase enzymeactivity changed only in cv Adamello during drought, with a furtherdecrease during rehydration, when initial and total activitieswere about 60% to 70% of control values (Fig. 4). During droughtand recovery the activation state of FBPase was maintained atthe control level in both cultivars (Fig. 4).

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Figure 3. Effects of dehydration and rehydration on the initial (I) and total (T) activities and activation state (I/T) of G3PDH in the wheat cvs Adamello and Ofanto. Bars represent the SE (n = 10 repetitions from three independent experiments). One-way analysis of variance was used for comparisons between the means. Bars with different letters are significantly different at P $<=$ 0.01.

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Figure 4. Effects of dehydration and rehydration on the initial (I) and total (T) activities and activation state (I/T) of FBPase in the wheat cvs Adamello and Ofanto. Bars represent the SE (n = 10 repetitions from three independent experiments). One-way analysis of variance was used for comparisons between the means. Bars with different letters are significantly different at P $<=$ 0.01.

In cv Adamello drought caused a general decrease in pigment contents, including chlorophyll a, lutein, neoxanthin, and $beta$ -carotene.However, all pigments recovered to control values after 4 d ofrehydration (Table III). This pattern of change was not evidentin cv Ofanto, in which all pigments did not change statistically.The chlorophyll a/b ratio decreased significantly during droughtin cv Adamello, whereas the difference was not significant incv Ofanto. Drought did not induce significant changes in the poolsize of xanthophyll-cycle components expressed on the basis ofdry weight in either cultivar. There was only a slight drought-inducedincrease in V+A+Z expressed on the basis of chlorophyll a in cvAdamello. The content of Z+A on the basis of the V+A+Z pool increasedby about 74% in cv Adamello under drought conditions comparedwith control plants (Table III). However, the recovery after 1d was complete, returning to control levels. The Z+A content didnot change in cv Ofanto.

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Table III. Pigment content of the wheat cvs Adamello and Ofanto during dehydration and rehydration

The rate of carbon dioxide assimilation and the photon yield of PSII showed a drought-induced decrease in both cultivars.However, this decrease was more pronounced in cv Adamello thanin cv Ofanto (Fig. 5). Accordingly, nonphotochemical quenchingincreased in drought-stressed plants compared with fully irrigatedcontrols: by about 48% in cv Ofanto and 70% in cv Adamello (Fig.5).

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Figure 5. Effects of dehydration on carbon dioxide assimilation rate, photochemical efficiency of PSII, and nonphotochemical quenching (NPQ) in the wheat cvs Adamello and Ofanto. Bars represent the SE from four independent experiments. One-way analysis of variance was used for comparisons between the means. Bars with different letters are significantly different at P $<=$ 0.01. Black bars, Control; white bars, drought-stressed.

	DISCUSSION

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Exposure to drought caused a significant decrease in dry mass accumulation in cv Adamello, whereas it had no significant effectsin cv Ofanto, even though both cultivars showed a significantdrop in $Psi$ _w (Table I). Variation in drought tolerance and in thevarious parameters analyzed were not explained by the observedslight differences in $Psi$ _w, since similar results were obtainedwith the same genotypes maintained at a similar $Psi$ _w but with differentsoil water contents (F. Navari-Izzo and A. Scartazza, unpublishedresults).

The GSH+GSSH and GSH contents under drought conditions were maintained at relatively high levels (Fig. 1) with respect tothose of other species (Buckland et al., 1991; Sgherri et al.,1994b; Schwanz et al., 1996). The drought-induced reduction inGSH content may indicate that both cultivars can rely on a largeamount of constitutive GSH to counteract the potentially harmfuleffects of drought. In agreement with the present results, a partialdegradation of the constitutive GSH was reported in Sporobolusstapfianus leaves subjected to dehydration (Sgherri et al., 1994b)and in sunflower plants under a severe drought (Sgherri et al.,1995). On the other hand, it has been reported that other species,such as the resurrection plant Boea hygroscopica, respond to droughtby increasing antioxidant synthesis (Sgherri et al., 1994a; Navari-Izzoet al., 1997).

Adaptation to drought may depend on different mechanisms, including the capacity to maintain high levels of antioxidants andto regenerate them through the induction of GR activity. A similareffect was evident in cv Adamello (Table II; Fig. 2). Furthermore,the increased capacity to metabolize hydrogen peroxide, whichwas evident from the observed drought-induced 2-fold increasein hydrogen peroxide-GP activity in cv Adamello (Table II), mayconfer tolerance to oxidative stress due to the increase in O₂· production under drought conditions (Quartacci et al., 1994).

Levels of GR and hydrogen peroxide-GP activities sufficient to maintain the balance of cellular components were present incv Ofanto, so there was no further increase in these enzyme activities.In cv Ofanto it is also possible that ascorbate peroxidase andmonodehydroascorbate reductase (Moran et al., 1994) and otherantioxidant enzymes (Zhang and Kirkham, 1994) may play a rolein maintaining low levels of hydrogen peroxide in the cells.

In previous experiments cv Ofanto plants subjected to two water-deficit cycles did not show changes in hydrogen peroxide contentand, after the second cycle, the O₂· production decreased in parallel with the activities of the glutathione-ascorbate-cycleenzymes (Menconi et al., 1995). In other experiments with maizeplants (Brown et al., 1995) subjected to gradual drought imposition(and hence involving a possible acclimation), GR activity andhydrogen peroxide levels were unaffected by drought. It has beensuggested that when drought is imposed slowly so that plants canacclimate, an increase in the O₂· level may be avoided (Sgherri et al., 1993). In the present experiment,35 d to reach a rather severe drought probably represents a periodlong enough to allow acclimation. Therefore, it is possible thatplants of the more tolerant cv Ofanto had the chance to acclimateto drought, avoiding exposure to oxidative stress. In such conditionsthere was no induction of antioxidative defenses.

Hydrogen peroxide, even at low concentrations, inhibits chloroplast sulfhydryl-containing enzymes by readily oxidizing theirsulfhydryl groups. Therefore, it is important for plant cellsto keep the levels of hydrogen peroxide low or to scavenge itefficiently. A low hydrogen peroxide content (Fig. 2) and a highGSH/GSSH ratio (Fig. 1) enabled both wheat cultivars to maintainthe sulfhydryl groups of soluble and membrane proteins in thereduced state (data not shown) during dehydration and rehydration.Moreover, the activation state of the enzymes containing essentialsulfhydryl groups, G3PDH (Fig. 3) and FBPase (Fig. 4), was notsignificantly affected by drought. Previous studies on Selaginellalepidophylla showed drought-induced decreases in sulfhydryl-containingenzyme activities (Harten and Eickmeier, 1986). In contrast, inthe resurrection plant B. hygroscopica the GSH/GSSH ratio, theG3PDH specific activity, and the percentage of sulfhydryl groupsof thylakoid proteins remained at control levels, whereas thepercentage of sulfhydryl groups of soluble proteins increased(Navari-Izzo et al., 1997).

During drought conditions maintaining low levels of hydrogen peroxide would also be reflected in a low rate of the Haber-Weissreaction, which is involved in the production of hydroxyl radicalsresponsible for lipid peroxidation. Accordingly, during dehydrationand rehydration in both cultivars, the unsaturation of total lipids(data not shown) and their content and the lipid hydroperoxidelevels (Table II) did not change. Therefore, the maintenance ofa low hydrogen peroxide level in both cultivars explains the lackof increase in the activities of GTs and GP on lipid hydroperoxideand t-butyl hydroperoxide (Table II).

The more drought-sensitive cv Adamello showed a decrease in chlorophyll a, the chlorophyll a/b ratio, and carotenoid pigmentsduring dehydration (Table III). A drought-induced reduction inpigment contents was previously reported in several species, includingpea (Moran et al., 1994) and Nerium oleander (Demmig-Adams etal., 1988). Photoinhibition and photodestruction of pigments maycontribute to such changes. In addition, the photosynthetic apparatusmay show acclimation responses such as changes in the relativeproportion of stacked and unstacked membrane domains (Andersonand Aro, 1994).

In cv Ofanto the lack of changes in pigment content and composition under drought conditions (Table III) indicates the capacityto preserve the photosynthetic apparatus. In agreement with thishypothesis, the drought-induced decline in the actual PSII photonyield was more marked in cv Adamello than in cv Ofanto (Fig. 5).Similarly, the net carbon dioxide assimilation rate at the endof the drought period decreased by only 36% in cv Ofanto, whereasit declined by about 84% in cv Adamello (Fig. 5).

Although neither cultivar showed significant changes in the pool size of xanthophyll-cycle components, a drought-induced increasein (Z+A)/(V+A+Z) was evident in cv Adamello (Table III). This mayreflect an increased excessive energy in the pigment bed and aconsequent increased need for radiationless dissipation. Accordingly,after exposure to drought, cv Adamello showed a higher increasein nonradiative energy dissipation, estimated as nonphotochemicalquenching, than cv Ofanto (Fig. 5). The fact that cv Ofanto didnot show significant changes in the pool size and compositionof V+A+Z in response to drought and subsequent rehydration (TableIII) may be explained by its higher total rate of electron transportcompared with cv Adamello. Therefore, in cv Ofanto the photosyntheticelectron transport was probably sufficient to preclude the buildupof excess energy in PSII. Zeaxanthin seems to be involved in thedevelopment of nonphotochemical quenching and nonradiative energydissipation, according to numerous previous reports (for reviews,see Demmig-Adams and Adams, 1992; Pfündel and Bilger, 1994; Hortonet al., 1996; Gilmore, 1997), and may be important in preventingirreversible damage in cv Adamello. However, zeaxanthin does notseem to play a crucial role in determining differences in droughttolerance between these two wheat cultivars.

The link between the xanthophyll cycle, ascorbate content, and redox state via ascorbate $left-arrow$ GSH $left-arrow$ NADPH is well known (Bochet al., 1994); therefore, in cv Adamello the drought-induced GRinduction and the consequent increase of the GSH/GSSH ratio maybe related to zeaxanthin formation and nonradiative energy dissipation.

In conclusion, the more drought-sensitive cv Adamello responded to a period of stress by reducing photosynthetic efficiencyand biomass accumulation. However, it is remarkable that all defensemechanisms assayed returned to control levels rapidly upon rehydration.This indicates that in this cultivar the defense mechanisms preventplants from suffering irreversible damages during the droughtperiod. On the other hand, the more drought-tolerant cv Ofantoseems able to avoid drought stress by maintaining a high photosyntheticactivity, and does not suffer an oxidative stress high enoughto trigger the defense mechanisms active in cv Adamello. Consequently,cv Ofanto under drought may maintain a growth rate similar tothat of well-watered control plants.

	FOOTNOTES

¹ This study was funded in part by Consiglio Nazionale delle Ricerche (no. 97.01525 CT06) and in part by Università di Pisa(Fondi di Ateneo, 1997).
^* Corresponding author, e-mail fnavari{at}agr.unipi.it; fax 39-50-598614.

Received August 19, 1998; accepted December 7, 1998.

ABBREVIATIONS

Abbreviations: FBPase, Fru-1,6-bisphosphatase. GP, glutathione peroxidase. GR, glutathione reductase. GT, glutathione transferase. G3PDH, NADP⁺-dependent glyceraldehyde-3-phosphate dehydrogenase. $Psi$ _w, water potential.

	LITERATURE CITED

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Antioxidative Defense System, Pigment Composition, and Photosynthetic Efficiency in Two Wheat Cultivars Subjected to Drought1

Copyright Clearance Center: 0032-0889/99/119//10 © 1999 American Society of Plant Physiologists

Antioxidative Defense System, Pigment Composition, and Photosynthetic Efficiency in Two Wheat Cultivars Subjected to Drought¹

Copyright Clearance Center: 0032-0889/99/119//10

© 1999 American Society of Plant Physiologists