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The Arabidopsis aba4-1 Mutant Reveals a Specific Function for Neoxanthin in Protection against Photooxidative Stress^[W]

^a Dipartimento Scientifico e Tecnologico, Università di Verona, I-37134 Verona, Italy
^b Laboratoire de Biologie des Sémences, Unité Mixte de Recherche 204, Institut National de la Recherche Agronomique–Institut National Agronomique Paris-Grignon, Institut Jean-Pierre Bourgin, 78026 Versailles Cedex, France
^c Laboratoire de Génétique et Biophysique des Plantes, Département d'Ecophysiologie Végétale et Microbiologie, Unité Mixte de Recherche 163, Commissariat à l'Energie Atomique–Centre National de la Recherche Scientifique, Université de la Méditerranée, 13288 Marseille, France

¹ To whom correspondence should be addressed. E-mail bassi{at}sci.univr.it; fax 39-045-802-7929.

	ABSTRACT

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
The aba4-1 mutant completely lacks neoxanthin but retains all other xanthophyll species. The missing neoxanthin in light-harvesting complex (Lhc) proteins is compensated for by higher levels of violaxanthin, albeit with lower capacity for photoprotection compared with proteins with wild-type levels of neoxanthin. Detached leaves of aba4-1 were more sensitive to oxidative stress than the wild type when exposed to high light and incubated in a solution of photosensitizer agents. Both treatments caused more rapid pigment bleaching and lipid oxidation in aba4-1 than wild-type plants, suggesting that neoxanthin acts as an antioxidant within the photosystem II (PSII) supercomplex in thylakoids. While neoxanthin-depleted Lhc proteins and leaves had similar sensitivity as the wild type to hydrogen peroxide and singlet oxygen, they were more sensitive to superoxide anions. aba4-1 intact plants were not more sensitive than the wild type to high-light stress, indicating the existence of compensatory mechanisms of photoprotection involving the accumulation of zeaxanthin. However, the aba4-1 npq1 double mutant, lacking zeaxanthin and neoxanthin, underwent stronger PSII photoinhibition and more extensive oxidation of pigments than the npq1 mutant, which still contains neoxanthin. We conclude that neoxanthin preserves PSII from photoinactivation and protects membrane lipids from photooxidation by reactive oxygen species. Neoxanthin appears particularly active against superoxide anions produced by the Mehler's reaction, whose rate is known to be enhanced in abiotic stress conditions.

	INTRODUCTION

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Carotenoids form a class of compounds synthesized in all photosynthetic organisms and in several species of etherotrophic bacteria and fungi (Britton et al., 1998). Carotenoids participate in coloring fruits, flowers, and leaves; they represent an important nutritional source for mammals, as precursor animal cell cofactors, like vitamin A. Due to their strong antioxidant activity, carotenoids are commercialized as human diet supplements and chemicals directed against the action of free radicals (Krinsky, 1979; Demmig-Adams and Adams, 2002). Both zeaxanthin (Zea) and lutein (Lute) are major antioxidant compounds in several human tissues, namely, in the eye (Krinsky et al., 2003). Neoxanthin (Neo) has been shown to induce apoptosis in prostate cancer cells (Kotake-Nara et al., 2005). Carotenoids play an irreplaceable role as components of the photosynthetic apparatus (Frank and Cogdell, 1996). In higher plants and algae, ß-carotene binds to chloroplast-encoded subunits of reaction center core complexes, while xanthophylls are chromophores of the peripheral antenna system composed of light-harvesting complexes (Lhc) (Bassi et al., 1993; Jansson, 1999). These xanthophylls, involved in light harvesting, are structural determinants of pigment protein architecture (Formaggio et al., 2001) and are essential for quenching triplet chlorophyll (³Chl*). Moreover, it has been proposed that Zea scavenges singlet oxygen (¹O₂) produced by photosynthetic activity when free in the lipid phase of thylakoids (Havaux and Niyogi, 1999).

Carotenoids form a class of compounds with very similar absorption characteristics in the visible region, both in term of molar extinction value and absorption wavelengths. Nevertheless, nature maintains a remarkably high degree of conservation in xanthophyll composition across a wide range of plant taxa: virtually all higher plants share the same xanthophyll species in very similar relative amounts (Frank and Cogdell, 1996; Cunningham and Gantt, 1998).

The few exceptions, like Cuscuta reflexa that lacks Neo, are found in parasitic plants with ill-functional photosynthetic apparatus (Bungard et al., 1999). The above data suggest that each xanthophyll species plays a specific role in photosynthetic function.

In recent years, much effort has been devoted to gaining new insight about the specific role of each xanthophyll using multiple approaches: (1) in vitro analysis of recombinant Lhc with different carotenoid contents (Croce et al., 1999b; Formaggio et al., 2001) and (2) isolation and in vivo characterization of mutants lacking specific xanthophylls (Pogson et al., 1996; Havaux and Niyogi, 1999; Lokstein et al., 2002; Baroli et al., 2003). Together, these efforts have improved our understanding of xanthophyll biology, suggesting that the function of individual xanthophyll species can be understood within the framework of their binding to Lhc proteins. Nevertheless, the function of Neo remains essentially unknown. Initial information has only been obtained from the analysis of recombinant Lhc proteins, while a mutant plant only lacking Neo has never been isolated. Neo depletion has to date only been obtained together with the accumulation of Zea at the expense of violaxanthin (Viola) (Rock and Zeevaart, 1991; Niyogi et al., 1998), thus obscuring the specific Neo-associated phenotype. Neo is an allenic monoepoxy-carotenoid (Goldsmith and Krinsky, 1960) accumulated in leaf tissue in the 9-cis conformation and produced from Viola in a reaction catalyzed by the neoxanthin synthase enzyme, which had been tentatively identified (Al Babili et al., 2000; Bouvier et al., 2000); it represents the final step in the so-called ß-branch of the carotenoid biosynthetic pathway. Finally, in vivo Neo represents an ultimate precursor of the plant growth regulator abscisic acid (ABA) (Milborrow, 2001).

Neo, like Viola, accounts for 14% of total carotenoids in low light conditions. Neo is mostly bound to the N1 binding site of the major LHCII complex (Croce et al., 1999a). The N1 site has been located in between helix C and the helix A/B cross by mutation analysis (Croce et al., 1999b), which was recently confirmed by x-ray crystallography (Liu et al., 2004). Minor amounts of Neo also bind to the minor Lhc proteins CP29 and CP26 at a different binding site, namely L2, in competition with Viola (Bassi et al., 1999; Gastaldelli et al., 2003). Neo is the carotenoid species that appears to be most strongly bound to Lhc proteins, its concentration in the lipid phase being the lowest among carotenoid species (Caffarri et al., 2001). In vitro, Neo is not essential for the folding of recombinant Lhcb proteins in the presence of Lute, Viola, or Zea (Formaggio et al., 2001), and attempts to fold any antenna complex in the presence of Neo alone have been unsuccessful (Giuffra et al., 1996; Hobe et al., 2000).

In this work, we have studied aba4-1, a mutant lacking Neo. The physiological and biochemical phenotype has been investigated in vivo for performance on growth and photoprotection; in vitro, Lhcb proteins have been purified and compared with those from the wild type by biochemical and spectroscopic methods. We found that Neo plays a specific role in the protection of Lhc proteins, the photosystem II (PSII) reaction center, and thylakoids from photooxidative stress and that its action is effective against the damaging effect of reactive oxygen species (ROS), particularly superoxide anion.

	RESULTS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
Pigment Composition
The mutant aba4-1 was isolated in a screen of an Arabidopsis thaliana Wasijliewska-2 accession T-DNA insertion collection described by North et al. (2007). Wild-type and aba4-1 plants grown in low light (120 µmol photons m^–2 s^–1) for 4 weeks were phenotypically indistinguishable, showing similar organ size and chlorophyll content per leaf surface. HPLC analysis of dark-adapted leaf pigment composition showed that Neo was absent in the mutant genotype, while an increase in Viola content was recorded (from 3.3 to 7.6 mol per 100 mol of chlorophylls a+b) that compensated for the missing Neo. Like the wild type, aba4-1 leaf tissue also contained the trans-isomer of Viola and had detectable amounts of 9-cis-Viola (up to 5.5% of the total xanthophyll pool) identified by HPLC as previously described (Snyder et al., 2004). Lute and ß-carotene content were essentially the same in both genotypes (Figure 1 , Table 1 ). The aba4-1 mutant phenotypes were mild compared with previously identified ABA-deficient mutants that exhibit vegetative tissue phenotypes, with no significant difference in growth characteristics. Indeed, ABA levels in unstressed leaves and seeds of aba4-1 mutants were higher than those of mutants npq2 (ABA-deficient1) (North et al., 2007) and aba3 (ABA-deficient3) (Schwartz et al., 1997). Most of the experiments described in this work were also performed with aba4-1 plants that had been supplemented with ABA by daily spraying (Llorente et al., 2000), and the results obtained with or without exogenous ABA treatment were similar.

View larger version (12K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 1. Analysis of Pigment Content in the Leaves of 4-Week-Old Wild-Type and aba4-1 Plants. Separation of lipid-soluble pigments was based on HPLC analysis. Each chromatogram represents absorbance (Abs) at 440 nm of pigments extracted from a leaf disc. Note the missing peak corresponding to Neo in aba4-1. N, Neo; V, Viola; L, Lute; ß, ß-carotene; chla, chlorophyll a; chlb, chlorophyll b.

View larger version (10K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 2. Activation of NPQ and Zea Synthesis Rate in Wild-Type and aba4-1 Leaves. (A) Induction of NPQ was measured during exposure of dark-adapted leaves to actinic light at 1200 µmol m–2 s–1. (B) Kinetics of deepoxidation index as measured on intact leaves during high-light (1200 µmol m–2 s–1) treatment at room temperature. Deepoxidation index was calculated as (1/2Anthera + Zea)/(Viola + Anthera + Zea). (C) Rate of accumulation of Zea in intact leaves exposed to high light at room temperature. The curve was normalized to 100 mol chlorophyll. Mean values (±SD) of three to five independent measurements are shown. Significantly different values (evaluated by Student's t test, P < 0.05) in comparison with the wild type are marked by an asterisk.

View larger version (7K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 3. Analysis of Room Temperature Chlorophyll Fluorescence during Photosynthesis. Fluorescence was monitored in intact, dark-adapted leaves (wild type, circles; aba4-1, squares). Thermal energy dissipation (NPQ; [A]), PSII redox state (qP; [B]), and photosynthetic efficiency (PSII; [C]) during photosynthesis. Leaves were illuminated for 20 min and parameters determined during steady state photosynthesis. Symbols and error bars show means ± SD (n 3).

To estimate if Neo content affects photoprotection, leaf discs from the wild type and aba4-1, floated on water, were illuminated with strong light (1800 µmol m^–2 s^–1) at room temperature; light-dependent bleaching of chlorophyll was followed by sampling discs at different times and quantifying their pigment content and lipid peroxidation level. aba4-1 leaf discs were clearly more sensitive to light stress than the wild type (Figure 4 ). After 6 h of treatment, 90% of chlorophyll was bleached in aba4-1 versus 35% in the wild type (Figure 4A). To investigate the level of membrane lipid peroxidation, the same leaf discs were analyzed for malondialdehyde content by HPLC (Havaux et al., 2005). In aba4-1 leaves, high-light treatment resulted in a higher level of lipid peroxidation with respect to the wild type (Figure 4B). Rates of carotenoid photoxidation were measured by HPLC analysis of leaf pigment content (Figures 4C and 4D). Results show that while carotenoid content decreased rapidly in aba4-1 leaves with respect to the wild type, no carotenoid species was preferentially destroyed.

View larger version (14K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 4. Photoprotection in Leaf Discs of the Wild Type and aba4-1. Leaf discs from the wild type and aba4-1 were treated with strong white light (1800 µmol m–2 s–1) at room temperature for different times, and the amount of chlorophylls, carotenoids, and lipid peroxides were evaluated. Data shown are the means ± SD from at least four independent experiments. Data sets with a significance level of P < 0.05 according to Student's t test are marked by an asterisk. (A) Kinetic of chlorophylls bleaching. (B) Time course of lipid peroxidation. Lipid peroxides were quantified by HPLC as thiobarbituric reactive substances. MDA, malondialdehyde. (C) Kinetics of carotenoids bleaching.

The sensitivity to photoxidative stress was also assessed on whole plants. Since aba4-1 plants have a larger pool of deepoxidable Viola (see above), higher levels of Zea are accumulated in plants under stress conditions with respect to wild-type plants (Figure 2C). Zea provides effective photoprotection through two mechanisms: (1) by the modulation of the thermal energy dissipation mechanism when it is bound to PSII subunits and (2) by acting as an efficient scavenger for ROS when it is free in the lipid phase. Previous reports have demonstrated that the photoprotective function mediated by Zea overlaps with other antioxidant mechanisms of the chloroplast, like tocopherols (Havaux et al., 2005), ascorbate (Muller-Moule et al., 2003), or other xanthophylls, like Lute (Niyogi et al., 2001). To avoid interference by different levels of Zea on the analysis of Neo contribution to photoprotection, we compared npq1 (nonphotochemical quenching1) with the double mutant aba4-1 npq1, which are both unable to accumulate Zea. Plants were kept under control conditions (24°C, 120 µmol m^–2 s^–1) or transferred to high light at low temperature (15°C, 1600 µmol m^–2 s^–1) and then analyzed for 6 d. The results are summarized in Figure 5 . Although aba4-1 npq1 plants did not show a strong photosensitive phenotype (although older leaves were more damaged than those of the wild type) (Figure 5A), more detailed analysis was performed after 6 d of treatment by determining the leaf content of molecules that are a target or indicator of photooxidative stress. The mutant aba4-1 npq1 underwent a significant reduction in leaf chlorophyll content and a strong accumulation of the antioxidant molecule tocopherol with respect to npq1 (Table 2 ). aba4-1 did not, however, show a similar increase in tocopherol content with respect to the wild type, although it accumulated twice as much Zea than the wild type. These results showed that the Neo-depleted aba4-1 npq1 genotype was more sensitive to photooxidative stress with respect to its Neo-containing reference npq1, while in aba4-1, the effects of Neo depletion were compensated for by an overaccumulation of Zea with respect to the wild type.

View larger version (58K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 5. Effect of High Light and Low Temperature on Wild-Type and Mutant Plants. (A) Wild-type, npq1, aba4-1, and aba4-1 npq1 plants were grown at 1600 µmol m–2 s–1 and 15°C for 6 d. HL, high light. (B) Photoinhibition of the same genotypes was measured daily as Fv/Fm during growth in high light at low temperature. During this treatment, plants were sprayed daily with 10 µM ABA to compensate for the reduced hormone content of the aba4-1 genotypes. Data are expressed as means ± SD; n = 7. Significantly lower Fv/Fm values (evaluated by Student's t test, P < 0.05) compared with the wild type are marked by an asterisk.

Effect of Exogenous Prooxidants on Leaf Chlorophyll Bleaching
The above results clearly showed that Neo-deficient plants were more sensitive to photooxidative stress than wild-type plants. We further analyzed the aba4-1 mutant to verify if Neo-dependent protection was directed against all ROS or was specific to a particular ROS species. ROS were either artificially produced in intact leaves by the photosensitizing compounds Rose Bengal (RB; a singlet oxygen generator) or Metronidazole (MZ; a superoxide anion generator), or leaves were directly treated with H₂O₂. Wild-type and aba4-1 leaves were vacuum-infiltrated with the above-mentioned chemicals, and thylakoid sensitivity was measured by quantifying the reduction of chlorophyll content over time (Figures 6A to 6C ). The sensitivity of the aba4-1 mutant and the wild type to H₂O₂ treatment was the same (Figure 6C), while aba4-1 was more sensitive than the wild type to singlet oxygen (produced by RB; Figure 6A) and, to a greater extent, to superoxide anion (produced by MZ; Figure 6B).

View larger version (9K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 6. Sensitivity of Wild-Type and aba4-1 Leaf Discs to Different ROS Species. Leaf discs were infiltrated with either 50 µM RB (A), 250 µM MZ (B), 250 mM hydrogen peroxide (C), or water and then floated on the same solution. Singlet oxygen was produced exogenously by illuminating samples with green light (photon flux density 100 µmol m–2 s–1); superoxide anion radicals were generated by illuminating with a fluorescence lamp (50 µmol m–2 s–1), and discs infiltrated with hydrogen peroxide were kept in the dark. ROS-mediated bleaching was followed by quantification of disc chlorophyll content. The gas phase during the experiment was air. Data are means ± SD; n = 4. Data sets with a significance level of P < 0.05 according to Student's t test are marked by an asterisk.

View larger version (12K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 7. Capacity for Scavenging Superoxide Anions. ROS were generated by the reaction of NADH and phenazine methosulfate (see Methods for details). The scavenging ability was measured as the inhibition of the increase in absorbance recorded at 530 nm, corresponding to nitroblue tetrazolium oxidation. Measurements were performed on thylakoids isolated from wild-type and aba4-1 plants (A) and purified Neo and Viola (B). Values are the mean of three measurements ± SD. All data sets for aba4-1 are significantly higher than the wild type according to Student's t test statistical analysis (P < 0.05).

To identify a possible effect of the altered pigment composition on the photoprotection of Lhcb proteins, we measured the photobleaching rates of Lhcb proteins purified from the wild type and aba4-1 by native flatbed isoelectric focusing (IEF). Different Lhcb proteins can be fractionated according to their pI as Lhcb1 + Lhcb2 (fraction 2), Lhcb4 (fraction 4), and Lhcb5 (fraction 5). In each case, the proteins purified from the Neo-deficient aba4-1 showed a corresponding increase in Viola and were more sensitive to photobleaching than the corresponding proteins from the wild type (Figure 8 ).

View larger version (7K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 8. Photobleaching Behavior of Purified Monomeric Lhcb. Flatbed IEF-purified Lhcb subunits from aba4-1 and wild-type plants. Photobleaching kinetics of decay of Qy transition absorbance was recorded for LHCII (A), CP29 (B), and CP26 (C) as described in Methods. Lhcb chlorophyll concentrations were adjusted to 8 µg/mL, and samples were cooled to 10°C during measurements. Values are the mean of three measurements ± SD. All aba4-1 data sets corresponding to times >8 min had significantly lower values (evaluated by Student's t test, P < 0.05) compared with the wild type. Closed symbols, wild-type Lhc; open symbols, aba4-1 Lhc.

Effect of Exogenous Prooxidants on Photoprotection of Isolated LHCs
The results obtained above (Figure 7, Table 3) indicated that Neo plays a role as a scavenger of ROS, such as singlet oxygen and superoxide anions. To verify if the selectivity to certain ROS could be ascribed to protein-bound Neo rather than to the small fraction (<1%) found free in the lipid phase (Caffarri et al., 2001), we extended the study to isolated major light-harvesting complex of PSII (LHCII). Trimeric LHCII, isolated by sucrose gradient ultracentrifugation from the wild type and aba4-1, underwent chemical bleaching of bound chlorophylls when exposed to the ROS generators used above for leaf infiltration. Prooxidant concentrations were chosen that resulted in a significant bleaching of wild-type trimers. In the wild type, both singlet oxygen (produced by RB) and hydrogen peroxide caused a progressive reduction in the Q_y absorption region of LHCII, without showing evidence of a differential contribution of bound Neo to the photoprotection ability of trimeric LHCII (Figures 9B and 9C ). By contrast, LHCII from aba4-1 was much more sensitive than the wild type to the superoxide anion produced by MZ (Figure 9A). The specificity for superoxide scavenging found in leaves was therefore reproduced with purified LHCII, whereas that for singlet oxygen was not. Sampling of LHCII during MZ treatment was performed at different times to measure the destruction rate of each xanthophyll species. Results obtained (see Supplemental Figure 3 online) are distinct with respect to those described on whole leaves vacuum-infiltrated with MZ (see Supplemental Figure 2 online): in this in vitro system, Neo in wild-type LHCII was destroyed more rapidly than the other carotenoids.

View larger version (8K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 9. Sensitivity of LHCII from the Wild Type and aba4-1 to Different ROS. LHCII isolated from solubilized thylakoids of the wild type and aba4-1 were analyzed by following the Qy transition absorbance decay when prooxidants were added to the solution: 250 µM MZ (A); 50 µM RB (B); and 1 M hydrogen peroxide (C). For details, see Methods. Lhcb chlorophyll concentrations were adjusted to 8 µg/mL. Data are expressed as means ± SD; n = 3. Data sets with a significance level of P < 0.05 according to Student's t test are marked by an asterisk.

View larger version (27K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 10. Sucrose Density Gradient Fractionation of the Wild Type and aba4-1 Solubilized Thylakoids and SDS-PAGE Analysis of Protein Content. (A) Thylakoid membranes from wild-type and aba4-1 plants were solubilized with -DM and loaded on sucrose gradients; for each gradient, fractions harvested are indicated. (B) Tris-Tricine SDS-PAGE analyses of thylakoid (lanes 1 and 2) and monomeric Lhcb (lanes 3 and 4) from wild-type (lanes 1 and 3) and aba4-1 (lanes 2 and 4) plants. MW, molecular weight marker. (C) Results of quantitative immunoblotting analysis of Lhcb proteins in wild-type versus aba4-1 thylakoid membranes. An antibody against CP47 was used as an internal standard. Significantly different values (P < 0.05) than the control genotype are marked by an asterisk. Data are expressed as means ± SD; n = 3. a.u., absorbance units.

	DISCUSSION

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
Neo Deficiency in Arabidopsis Results in a Compensatory Increase in Viola
Neo, together with Lute and Viola, is one of the three major xanthophylls of leaves: it is a mono-epoxy carotenoid, bound to the N1 site of LHCII as 9-cis-Neo localized between the helix A/helix B cross and helix C as determined by mutation analysis of recombinant proteins (Croce et al., 1999a, 1999b) and later confirmed by x-ray crystallography (Liu et al., 2004). Two additional pigment protein complexes also bind Neo (CP29 and CP26), while CP24 and Lhca1-4 do not bind Neo (Bassi et al., 1993). CP26 and CP29 do not have a N1 binding site; they bind Neo in site L2 in competition with Viola (Bassi et al., 1999; Gastaldelli et al., 2003).

Recombinant proteins, when refolded in vitro in the absence of Neo, bind an additional corresponding amount of Viola (Giuffra et al., 1996; Hobe et al., 2000). The same effect occurred in vivo in the aba4-1 mutant. As in LHCII purified from mutant leaves, one additional molecule of Viola was bound compared with LHCII from the wild type (Table 4). The thylakoid chlorophyll/carotenoide and chlorophyll a/b ratios, however, were not affected, which would not be expected due to the decrease in CP26 and, possibly, in the LHCII trimer connected to CP26. This apparent contradiction was reconciled by the observation that LHCII folded without Neo has a higher affinity for chlorophyll b, thus compensating for the reduced CP26 content of thylakoid membranes. A decrease in CP26 was reported in Zea accumulating genotypes npq2 and npq2 lut2 (lutein deficient2) (Havaux et al., 2004), which also lack Neo. The results presented here suggest that CP26 is destabilized in vivo by the lack of Neo rather than by the accumulation of Zea. By contrast, the major LHCII is maintained in the npq2 mutant (Connelly et al., 1997) in spite of the complete lack of Neo.

Depletion of Neo has been reported for C. reflexa, a parasitic plant with low photosynthetic activity (Bungard et al., 1999), where it is substituted by 9-cis-Viola in LHCII (Snyder et al., 2004). A similar situation occurred in aba4-1 LHCII. Spectral deconvolution of LHCII absorption spectra from aba4-1 revealed that a good fit can be obtained using the Viola spectral form shifted to the same absorption wavelength as Neo in the wild type (487 nm); since 9-cis-Neo (the stereoisomer bound to wild-type LHCII) and 9-cis-Viola have the same absorption spectra in organic solvents (Snyder et al., 2004), this indicates that Viola can bind to the N1 site in LHCII from aba4-1 in its 9-cis configuration. Since the 9-cis stereoisomer of Viola is not stable in organic solvents, even after heat-induced isomerization of all-trans xanthophylls (Niedzwiedzki et al., 2005), the low amounts of 9-cis-Viola that were detected probably derive from Viola bound to the N1 site, whereas xanthophyll bound to the L2 site would be in the all-trans configuration (Liu et al., 2004). The aba4-1 mutant therefore represents a useful tool for the determination of the physiological function of Neo and whether this function is different from that of Viola.

It has been suggested that Neo plays a role in stabilizing LHCII trimers (Ruban and Horton, 1999) due to the trimer/monomer ratio in npq2 mutants, which accumulate Zea and are depleted for Neo (Tardy and Havaux, 1996; Lokstein et al., 2002). As trimeric organization appeared to be unaltered in aba4-1 (Figure 10A), this suggests that monomerization is due to the accumulation of Zea with more than one Zea molecule per LHCII monomer (Connelly et al., 1997). This implies that a fraction of LHCII molecules has Zea in the L1 site, which must be occupied by Lute for trimerization (Lokstein et al., 2002) and not Zea or Viola (Havaux et al., 2004).

PSII function and overall photosynthetic rate were not affected in the aba4-1 mutant, suggesting that Neo was not essential for plant survival in mild environmental conditions. The only noticeable effect was the decrease in CP26 content mentioned above, which was compensated for by a corresponding increase in CP29 and CP24 similar to that previously observed for LHCII (Ruban et al., 2003). Nevertheless, CP26 antisense plants did not have a photosensitive phenotype (Andersson et al., 2001).

Resistance to Photooxidative Stress Is Decreased in aba4-1 with Respect to the Wild Type
Carotenoids are essential for the protection of the chloroplast from photoxidative stress (Niyogi, 1999). Previous work with recombinant proteins suggested that Neo might function in the scavenging of ROS generated from the incomplete quenching of chlorophyll triplets (Croce et al., 1999a). Nevertheless, this hypothesis could not be verified in vivo since the only plants available to date depleted in Neo also undergo substitution of Viola by Zea. Zea strongly affects PSII function by decreasing chlorophyll fluorescence lifetime through a conformational change of Lhc proteins (Moya et al., 2001; Dall'Osto et al., 2005) and also prevents photooxidative damage (Havaux and Niyogi, 1999; Baroli et al., 2003, 2004); therefore, the contribution of Neo to photoprotection function could easily be masked by the accumulation of Zea in npq2 (Niyogi et al., 1998; Baroli et al., 2003; Dall'Osto et al., 2005). The aba4-1 mutant specifically lacks Neo and appears to be more sensitive to stress caused by high-light treatment, as leaf discs excised from aba4-1 bleached faster under high light than discs from the wild type (Figure 4A). This effect was due to a higher sensitivity to the ROS produced by the photosynthetic machinery, as proven from increased lipid peroxidation (Figure 4B), and cannot be ascribed to the reduced content in ABA (see Supplemental Figure 1 online). Whole plants were more resistant to high-light treatment than excised leaf discs. aba4-1 plants do not have a strong in vivo phenotype compared with the wild type (Figure 5A). Nevertheless, the high-light treatment of aba4-1 plants induced a twofold increase in Zea synthesis (Table 2) with respect to wild-type plants. To eliminate the photoprotective effect of Zea, we compared aba4-1 npq1 with npq1 during high-light treatment. In this situation, aba4-1 npq1 plants were more sensitive than npq1 based on the rate of chlorophyll photobleaching, PSII photoinhibition, and overproduction of tocopherol. Moreover, while the Neo- or Zea-containing genotypes rapidly recovered from the initial damage, the double mutant did not fully recover photosynthetic efficiency, even after 1 week, despite the accumulation of higher amounts of the antioxidant tocopherol. Alternatively, the photosensitive phenotype of aba4-1 could, in principle, be related to reduced content in ABA. However, this hypothesis seems rather unlikely due to the following reasons: (1) leaf discs from aba3-1 do not show higher sensitivity to high light with respect to wild-type leaves, implying that photoxidation measured on aba4-1 leaves cannot be related to deficiency in ABA or any other metabolite of Neo; (2) it appears unlikely that the effects of ABA deficiency, absent on detached leaves, would appear on whole plants grown in high-humidity conditions and sprayed daily with ABA. This view is supported by several reports (e.g., Ruggiero et al., 2004) that demonstrated the efficiency of ABA supplementation on restoring the wild-type phenotype.

We conclude that the substitution of Neo with Viola in the chloroplasts of aba4-1 affects the capacity of the photosynthetic apparatus to face oxidative stress. This is compensated for by the synthesis of Zea and tocopherol, in the absence of which, the increased sensitivity of Neo-minus genotypes to photooxidative stress becomes evident in either leaf discs or whole plants.

What Can Neo Do That Viola Cannot?
In the aba4-1 mutant, the replacement of the missing Neo by Viola yielded a decrease in stress resistance, while the overaccumulation of Viola, in the presence of Neo, was shown to increase photoprotection in vivo (Davison et al., 2002). This suggests a distinct role for the different xanthophyll species in photoprotection. Cooperative effects on photoprotection by different xanthophyll species has been suggested in early experiments using recombinant Lhcb proteins reconstituted with different xanthophylls (Croce et al., 1999b). These showed that Lhcb1 reconstituted with Lute + Viola + Neo was more resistant to photobleaching in the presence of oxygen than proteins reconstituted with any single xanthophyll, implying a specific role for each.

This hypothesis has been confirmed in measurements of chlorophyll photobleaching in leaves challenged with either singlet oxygen, superoxide anion, or H₂O₂, which shows that Neo-containing leaves were selectively more resistant to damage from superoxide and singlet oxygen (Figure 7). The selective photoprotection against superoxide was reproduced in isolated LHCII, while the damage by hydrogen peroxide and singlet oxygen was identical in Neo and Viola binding proteins (Figure 9). Such evidence supports the idea that one function of Neo is to confer higher resistance to superoxide anions, a ROS species mainly produced by the Mehler's reaction when PSI electron acceptors are overreduced (Asada, 1999). Chloroplasts activate an antioxidant network to reduce damage by singlet oxygen and superoxide anions: these mechanisms involve (1) direct scavenging by carotenoids and (2) enzymatic detoxification of mediated by SOD and ascorbate peroxidase (Sano and Asada, 1994; Gomez et al., 2004). Our results with MZ in vivo clearly show that in high light, Viola, which substitutes for Neo in aba4-1, cannot effectively counteract the higher rate of superoxide anion or singlet oxygen production, leading to pigment bleaching. This conclusion for was supported further by the effects of SOD inhibition in aba4-1 leaves: leaf infiltration with the SOD inhibitor diethyl-dithio-carbamic acid, without direct addition of exogenous superoxide, increased the level of photoxidative bleaching of leaf pigments (Table 3). Measurements of the scavenging capacity of either thylakoid membranes or purified pigments (Figure 7) confirmed that Neo molecules were more efficient as ROS scavengers than Viola. These results suggest an overlapping function between Neo and enzymatic scavenger systems in the chloroplast. In this respect, it is of interest to note that the double mutant aba4-1 npq1, depleted in both Zea and Neo, showed an enhancement of the phenotype. Zea has previously been shown to have a ROS scavenger effect when present as a free pigment released in the lipid phase (Havaux and Niyogi, 1999; Baroli et al., 2003, 2004). Thus, depletion of Zea and Neo simultaneously would deactivate two components of the photoprotective system against ROS in the lipid phase. Therefore, Neo would appear to be an effective ROS scavenger that forms part of a diverse group of antioxidant molecules that act in the chloroplast, like Zea (Havaux and Niyogi, 1999), ascorbate (Muller-Moule et al., 2002), and tocopherol (Havaux et al., 2005). In principle, we cannot exclude the possibility that the results described above are due to some kind of disruption of the normal Lhcb protein structure and function induced by binding of Viola to site N1, normally occupied by Neo, which could increase sensitivity to ROS, rather than to the deficiency in Neo. To distinguish between these two hypotheses is anything but easy: ROS scavenging measurements both on isolated pigments and thylakoids clearly support the antioxidant role of Neo; on the other hand, the higher sensitivity of aba4-1 detached leaves to high light could be (at least in part) related to Lhc conformational change due to substitution of Neo with Viola. It should be noted, however, that Neo is bound to LHCII by one side only. It happens that Neo and Viola differ by the part of the molecule that protrudes out from the LHCII protein structure, while the bound end has the same structure (Liu et al., 2004). This explains why Viola can substitute for Neo in LHCII structure and why the differences in the absorption spectra induced by the exchange are very small (see Supplemental Figure 5 online). We note that substitution of other xanthophylls in sites L2 or L1 yield much stronger effects (Holt et al., 2003), and even the emptiness of site N1 does not affect LHCII function (Connelly et al., 1997). Thus, although disruption of LHCII structure by binding of Viola to the site cannot be excluded, we do not favor this hypothesis.

Neo-Dependent Photoprotection in Leaves and in Purified Lhc Proteins
As increased photoprotection of wild type versus aba4-1 was observed not only in leaves but also in purified Lhc proteins exposed to the action of different ROS species produced by sensitizers, this suggests that PSII antenna proteins in particular require protection against superoxide anions. In vivo, this ROS species is mainly produced in the Mehler's reaction by PSI upon overreduction of electron acceptors, while overexcitation of PSII essentially yields singlet oxygen, which is the major cause of PSII photoinhibition (Krieger-Liszkay, 2005).

Previous work with cold-stressed barley (Hordeum vulgare) has shown that treatments increasing the Mehler's reaction and/or suppressing SOD activity not only induce PSI damage but also elicit PSII photoinhibition, implying that Q_a reduction might be only one source for photoinhibition (Tjus et al., 1998). These reports suggest two possible scenarios: (1) the effect of Neo might be directed against ROS originating outside the PSII chlorophyll binding proteins and diffusing toward PSII reaction centers, namely, superoxide anion originated from Mehler's reaction; and (2) Viola binding complexes could be structurally more sensitive to the ROS action. When observing the structure of the LHCII trimer (Figure 11) (Liu et al., 2004), it is striking to note that Lute molecules bound to L1 and L2 sites are buried deep inside the protein structure, and Viola in V1 site is shielded by the interaction of a neighbor LHCII monomer. Neo in N1, instead, protrudes out from the structure by most of its length and is thus exposed to the surrounding lipid phase and to reactive species diffusing in it. Due to the short lifetime of singlet oxygen, it is unlikely that scavenging of this ROS would be the major target of Neo action at the periphery of the PSII supercomplex, while the superoxide anions produced by PSI at grana margins are long-lived and may diffuse toward PSII reaction centers; furthermore, radical chain reactions triggered by ROS attack to membrane lipids could easily propagate through the double layer. An alternative hypothesis is that superoxide is produced in PSII. In effect, it has been reported that superoxide anions are produced by the PSII acceptor side in purified PSII preparations (Pospisil et al., 2004, 2006). At present, it is not clear if superoxide anions are a product of PSII in vivo.

View larger version (89K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 11. Localization of Neo Molecules in Higher Plant Antennae. LHCII structure is based on data from Liu et al. (2004). The position of Neo molecules, protruding with allenic group exposed outside the complex, is highlighted in blue. Other cofactors bound are indicated as follows: chlorophylls (green), Lute in L2 (orange), and Lute in L1 (purple).

Possible Mechanism of Action for Neo Protection from ROS
It is known that the structural features of different carotenoids are important for their antioxidant activity, and we show here that Neo is more active than Viola in scavenging superoxide anions (Figure 7). The allenic function of Neo, which is exposed in the lipid phase from the LHCII structure (Liu et al., 2004), is the distinctive feature with respect to Viola, while the rest of the molecule is identical and might be responsible for increased reactivity. We are presently unable to distinguish between the two major pathways produced by the reaction of carotenoids with radical species, namely, the formation of a carotenoid radical adduct or the production of a carotenoid radical cation by electron transfer (Burton and Ingold, 1984; Woodall et al., 1997a, 1997b). Nevertheless, the observation that exposure of Neo to superoxide generators leads to preferential destruction of Neo in purified LHCII but not in leaves (see Supplemental Figures 2 and 3 online) suggests that Neo might be involved in the formation of radicals that are then detoxified by a partner molecule, absent in the purified LHCII sample. A candidate for this function is tocopherol, whose synergistic action with carotenoids in photoprotection has been previously highlighted (Havaux et al., 2005). Construction of an aba4 vte1 double mutant is in progress as a tool for clarifying the mechanism of Neo action.

Conclusion
We have shown a specific effect for Neo in scavenging superoxide anions, which could account for the aba4-1 higher sensitivity to high-light stress and to inhibitors of chloroplastic SOD. Superoxide anions are thought to be mainly produced by the Mehler's reaction in conditions leading to overreduction of electron acceptors to PSI, which is located in distinct membrane domains with respect to PSII; thus, we propose that the binding site of Neo, protruding outwards from LHCII trimers and located at the periphery of PSII supercomplexes, could be particularly effective in protecting PSII from superoxide anions diffusing from stroma membranes into grana partitions. Neo is also effective in forming Lhc proteins that are better protected from superoxide damage, thus supporting the view that different xanthophyll species play complementary roles in the photoprotection of the chloroplast. We also reported evidence of a limited conformational change of Lhc subunits due to higher Viola content. It cannot be excluded that these structural changes, although of small amplitude, could in principle contribute to the ROS-specific sensitivity of aba4-1. This effect would add to the well-demonstrated superoxide scavenging ability of Neo. It can be asked why plants would need protection against ROS, in addition to that provided by Zea, which has been shown to be effective (Havaux and Niyogi, 1999; Baroli et al., 2003; Dall'Osto et al., 2005) and to become available when stress is induced in wild-type plants. A constitutive accumulation of Zea induces strong thermal degradation by shortening ¹Chl* lifetime and decreasing the probability of excitation trapping by PSII (Moya et al., 2001; Polivka et al., 2002), thus leading to reduced plant growth in limiting light (Dall'Osto et al., 2005). In fact, Zea accumulating genotypes lut2 npq2 and npq2 are phototolerant but dwarf (Havaux et al., 2004). It is clear that plants pay off photoprotection by Zea with a reduction in growth or even arrest. Photoprotection by Lute, Viola, and Neo can be more selective and/or less effective than that of Zea without preventing plant growth.

	METHODS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
Plant Material
The npq1 mutant was a kind gift of K. Niyogi (Berkeley, CA). aba3-1 (Col-0) was provided by Institut National de la Recherche Agronomique. aba4-1 (Wass-2) and aba4-3 (Col-0) were isolated as described by North et al. (2007). The genotype aba4-1 npq1 was obtained by crossing single mutant plants and selecting progeny by pigment analysis after high-light treatment.

Wild-type (accessions Wassilijewska-2 and Col-0) and mutant plants were grown on compost in a growth chamber for 4 weeks under controlled conditions (120 µmol photons m^–2 s^–1, 24°C, 8 h light/16 h dark, 80% relative humidity).

Stress Conditions
For high-light treatments, light was provided by 150-W halogen lamps (Focus 3; Prisma). Short-term high-light treatment was performed for 1 h at 1200 µmol photons m^–2 s^–1 at room temperature (24°C) to measure Zea accumulation on detached leaves. Photooxidative stress was induced in whole plants by a strong light treatment at low temperature. Whole Arabidopsis thaliana plants (40 d old) were exposed to high light (1600 µmol photon m^–2 s^–1 with a day/night photoperiod of 12 h/12 h) at low temperature (15°C/10°C, day/night air temperature, 80% relative humidity) for 7 d. Plants were daily sprayed with 100 µM ABA.

Light stress was also imposed on 1-cm diameter leaf discs. The discs were harvested from mature leaves. Leaf discs were vacuum-infiltrated with water and kept floating on water and then exposed to white light (photon flux density 1800 µmol m^–2 s^–1 for chlorophyll bleaching) at room temperature.

In Vivo Fluorescence and NPQ Measurements
NPQ of chlorophyll fluorescence, photochemical quenching (qP), and PSII yield (_PSII) was measured with a PAM 101 fluorimeter (Walz). Minimum fluorescence (F₀) was measured with a 0.15 µmol m^–2 s^–1 beam, F_m was determined with a 1-s light pulse (5000 µmol m^–2 s^–1), and white continuous light (1200 µmol m^–2 s^–1) was supplied by a KL1500 halogen lamp (Schott). NPQ was calculated according to the following equation (Van Kooten and Snel, 1990): NPQ = (F_m –F'_m)/F'_m, where F_m is the maximum chlorophyll fluorescence from dark-adapted leaves and F'_m is the maximum chlorophyll fluorescence under actinic light exposition. Measurements of room temperature fluorescence during photosynthesis with illumination from a model KL1500 lamp (Schott) and calculation of fluorescence parameters and NPQ of chlorophyll fluorescence were performed as described previously (Walters and Horton, 1995). Leaf discs were given 20 min of illumination, and PSII redox state and photosynthetic efficiency were determined during steady state photosynthesis. After fluor