Chloroplasts lacking class I glutaredoxins are functional but show a delayed recovery of protein cysteinyl redox state after oxidative challenge.

Redox status of protein cysteinyl residues is mediated via glutathione (GSH)/glutaredoxin (GRX) and thioredoxin (TRX)-dependent redox cascades. An oxidative challenge can induce post-translational protein modifications on thiols, such as protein S-glutathionylation. Class I GRX are small thiol-disulfide oxidoreductases that reversibly catalyse S-glutathionylation and protein disulfide formation. TRX and GSH/GRX redox systems can provide partial backup for each other in several subcellular compartments, but not in the plastid stroma where TRX/light-dependent redox regulation of primary metabolism takes place. While the stromal TRX system has been studied at detail, the role of class I GRX on plastid redox processes is still unknown. We generate knockout lines of GRXC5 as the only chloroplast class I GRX of the moss Physcomitrium patens. While we find that PpGRXC5 has high activities in GSH-dependent oxidoreductase assays using hydroxyethyl disulfide or redox-sensitive GFP2 as substrates in vitro, Δgrxc5 plants show no detectable growth defect or stress sensitivity, in contrast to mutants with a less negative stromal EGSH (Δgr1). Using stroma-targeted roGFP2, we show increased protein Cys steady state oxidation and decreased reduction rates after oxidative challenge in Δgrxc5 plants in vivo, indicating kinetic uncoupling of the protein Cys redox state from EGSH. Compared to wildtype, protein Cys disulfide formation rates and S-glutathionylation levels after H2O2 treatment remained unchanged. Lack of class I GRX function in the stroma did not result in impaired carbon fixation. Our observations suggest specific roles for GRXC5 in the efficient transfer of electrons from GSH to target protein Cys as well as negligible cross-talk with metabolic regulation via the TRX system. We propose a model for stromal class I GRX function in efficient catalysis of protein dithiol/disulfide equilibria upon redox steady state alterations affecting stromal EGSH and highlight the importance of identifying in vivo target proteins of GRXC5.

The impact of long-term acclimation to different growth light intensities on the regulation of zeaxanthin epoxidase in different plant species.

Proper short- and long-term acclimation to different growth light intensities is essential for the survival and competitiveness of plants in the field. High light exposure is known to induce the down-regulation and photoinhibition of photosystem II (PSII) activity to reduce photo-oxidative stress. The xanthophyll zeaxanthin (Zx) serves central photoprotective functions in these processes. We have shown in recent work with different plant species (Arabidopsis, tobacco, spinach and pea) that photoinhibition of PSII and degradation of the PSII reaction center protein D1 is accompanied by the inactivation and degradation of zeaxanthin epoxidase (ZEP), which catalyzes the reconversion of Zx to violaxanthin. Different high light sensitivity of the above-mentioned species correlated with differential down-regulation of both PSII and ZEP activity. Applying light and electron microscopy, chlorophyll fluorescence, and protein and pigment analyses, we investigated the acclimation properties of these species to different growth light intensities with respect to the ability to adjust their photoprotective strategies. We show that the species differ in phenotypic plasticity in response to short- and long-term high light conditions at different morphological and physiological levels. However, the close co-regulation of PSII and ZEP activity remains a common feature in all species and under all conditions. This work supports species-specific acclimation strategies and properties in response to high light stress and underlines the central role of the xanthophyll Zx in photoprotection.

The Amount of Zeaxanthin Epoxidase But Not the Amount of Violaxanthin De-Epoxidase Is a Critical Determinant of Zeaxanthin Accumulation in Arabidopsis thaliana and Nicotiana tabacum.

The generation of violaxanthin (Vx) de-epoxidase (VDE), photosystem II subunit S (PsbS) and zeaxanthin (Zx) epoxidase (ZEP) (VPZ) lines, which simultaneously overexpress VDE, PsbS and ZEP, has been successfully used to accelerate the kinetics of the induction and relaxation of non-photochemical quenching (NPQ). Here, we studied the impact of the overexpression of VDE and ZEP on the conversion of the xanthophyll cycle pigments in VPZ lines of Arabidopsis thaliana and Nicotiana tabacum. The protein amount of both VDE and ZEP was determined to be increased to about 3- to 5-fold levels of wild-type (WT) plants for both species. Compared to WT plants, the conversion of Vx to Zx, and hence VDE activity, was only marginally accelerated in VPZ lines, whereas the conversion of Zx to Vx, and thus ZEP activity, was strongly increased in VPZ lines. This indicates that the amount of ZEP but not the amount of VDE is a critical determinant of the equilibrium of the de-epoxidation state of xanthophyll cycle pigments under saturating light conditions. Comparing the two steps of epoxidation, particularly the second step (antheraxanthin to Vx) was found to be accelerated in VPZ lines, implying that the intermediate Ax is released into the membrane during epoxidation by ZEP.

Zeaxanthin Epoxidase Activity Is Downregulated by Hydrogen Peroxide.

The xanthophyll zeaxanthin (Zx) serves important photoprotective functions in chloroplasts and is particularly involved in the dissipation of excess light energy as heat in the antenna of photosystem II (PSII). Zx accumulates under high-light (HL) conditions in thylakoid membranes and is reconverted to violaxanthin by Zx epoxidase (ZEP) in low light or darkness. ZEP activity is completely inhibited under long-lasting HL stress, and the ZEP protein becomes degraded along with the PSII subunit D1 during photoinhibition of PSII. This ZEP inactivation ensures that high levels of Zx are maintained under harsh HL stress. The mechanism of ZEP inactivation is unknown. Here, we investigated ZEP inactivation by reactive oxygen species (ROS) under in vitro conditions. Our results show that ZEP activity is completely inhibited by hydrogen peroxide (H2O2), whereas inhibition by singlet oxygen or superoxide seems rather unlikely. Due to the limited information about the amount of singlet oxygen and superoxide accumulating under the applied experimental conditions, however, a possible inhibition of ZEP activity by these two ROS cannot be generally excluded. Despite this limitation, our data support the hypothesis that the accumulation of ROS, in particular H2O2, might be responsible for HL-induced inactivation of ZEP under in vivo conditions.

H+ Transport by K+ EXCHANGE ANTIPORTER3 Promotes Photosynthesis and Growth in Chloroplast ATP Synthase Mutants.

The composition of the thylakoid proton motive force (pmf) is regulated by thylakoid ion transport. Passive ion channels in the thylakoid membrane dissipate the membrane potential (Δψ) component to allow for a higher fraction of pmf stored as a proton concentration gradient (ΔpH). K+/H+ antiport across the thylakoid membrane via K+ EXCHANGE ANTIPORTER3 (KEA3) instead reduces the ΔpH fraction of the pmf. Thereby, KEA3 decreases nonphotochemical quenching (NPQ), thus allowing for higher light use efficiency, which is particularly important during transitions from high to low light. Here, we show that in the background of the Arabidopsis (Arabidopsis thaliana) chloroplast (cp)ATP synthase assembly mutant cgl160, with decreased cpATP synthase activity and increased pmf amplitude, KEA3 plays an important role for photosynthesis and plant growth under steady-state conditions. By comparing cgl160 single with cgl160 kea3 double mutants, we demonstrate that in the cgl160 background loss of KEA3 causes a strong growth penalty. This is due to a reduced photosynthetic capacity of cgl160 kea3 mutants, as these plants have a lower lumenal pH than cgl160 mutants, and thus show substantially increased pH-dependent NPQ and decreased electron transport through the cytochrome b 6 f complex. Overexpression of KEA3 in the cgl160 background reduces pH-dependent NPQ and increases photosystem II efficiency. Taken together, our data provide evidence that under conditions where cpATP synthase activity is low, a KEA3-dependent reduction of ΔpH benefits photosynthesis and growth.

The zeaxanthin epoxidase is degraded along with the D1 protein during photoinhibition of photosystem II.

The xanthophyll zeaxanthin is synthesized in chloroplasts upon high light exposure of plants and serves central photoprotective functions. The reconversion of zeaxanthin to violaxanthin is catalyzed by the zeaxanthin epoxidase (ZEP). ZEP shows highest activity after short and moderate high light periods, but becomes gradually down-regulated in response to increasing high light stress along with down-regulation of photosystem II (PSII) activity. ZEP activity and ZEP protein levels were studied in response to high light stress in four plant species: Arabidopsis thaliana, Pisum sativum, Nicotiana benthamiana and Spinacia oleracea. In all species, ZEP protein was degraded during photoinhibition of PSII in parallel with the D1 protein of PSII. In the presence of streptomycin, an inhibitor of chloroplast protein synthesis, photoinhibition of PSII and ZEP activity as well as degradation of D1 and ZEP protein was strongly increased, indicating a close correlation of ZEP regulation with PSII photoinhibition and repair. The concomitant high light-induced inactivation/degradation of ZEP and D1 prevents the reconversion of zeaxanthin during photoinhibition and repair of PSII. This regulation of ZEP activity supports a coordinated degradation of D1 and ZEP during photoinhibition/repair of PSII and an essential photoprotective function of zeaxanthin during the PSII repair cycle.